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Goat Medicine Second Edition

Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Goat Medicine Second Edition

Mary C. Smith, DVM Diplomate, American College of Theriogenologists Professor, Department of Population Medicine and Diagnostic Sciences New York State College of Veterinary Medicine Cornell University Ithaca, New York

David M. Sherman, DVM, MS Diplomate, American College of Veterinary Internal Medicine Clinical Associate Professor Department of Environmental and Population Health Cummings School of Veterinary Medicine at Tufts University North Grafton, Massachusetts

A John Wiley & Sons, Inc., Publication

First Edition first published 1994, Lea & Febiger Second Edition first published 2009 © 2009 Wiley-Blackwell Blackwell Publishing was acquired by John Wiley & Sons in February 2007. Blackwell’s publishing program has been merged with Wiley’s global Scientific, Technical, and Medical business to form Wiley-Blackwell. Editorial Office 2121 State Avenue, Ames, Iowa 50014-8300, USA For details of our global editorial offices, for customer services, and for information about how to apply for permission to reuse the copyright material in this book, please see our Website at www.wiley.com/wiley-blackwell. Authorization to photocopy items for internal or personal use, or the internal or personal use of specific clients, is granted by Blackwell Publishing, provided that the base fee is paid directly to the Copyright Clearance Center, 222 Rosewood Drive, Danvers, MA 01923. For those organizations that have been granted a photocopy license by CCC, a separate system of payments has been arranged. The fee codes for users of the Transactional Reporting Service are ISBN-13: 978-0-7817-9643-9/2009. Designations used by companies to distinguish their products are often claimed as trademarks. All brand names and product names used in this book are trade names, service marks, trademarks or registered trademarks of their respective owners. The publisher is not associated with any product or vendor mentioned in this book. This publication is designed to provide accurate and authoritative information in regard to the subject matter covered. It is sold on the understanding that the publisher is not engaged in rendering professional services. If professional advice or other expert assistance is required, the services of a competent professional should be sought. Library of Congress Cataloguing-in-Publication Data Smith, Mary C. Goat medicine / Mary Smith, David Sherman. – 2nd ed. p. cm. Includes bibliographical references and index. ISBN-13: 978-0-7817-9643-9 (alk. paper) ISBN-10: 0-7817-9643-1 (alk. paper) 1. Goats–Diseases. 2. Goats–Diseases–Tropics. I. Sherman, David M.

II. Title.

SF968.S63 2009 636.3′9089–dc22 2008049843 A catalog record for this book is available from the U.S. Library of Congress. Set in 10/12 pt Palatino by SNP Best-set Typesetter Ltd., Hong Kong Printed in Singapore Disclaimer The contents of this work are intended to further general scientific research, understanding, and discussion only and are not intended and should not be relied upon as recommending or promoting a specific method, diagnosis, or treatment by practitioners for any particular patient. The publisher and the authors make no representations or warranties with respect to the accuracy or completeness of the contents of this work and specifically disclaim all warranties, including without limitation any implied warranties of fitness for a particular purpose. In view of ongoing research, equipment modifications, changes in governmental regulations, and the constant flow of information relating to the use of medicines, equipment, and devices, the reader is urged to review and evaluate the information provided in the package insert or instructions for each medicine, equipment, or device for, among other things, any changes in the instructions or indication of usage and for added warnings and precautions. Readers should consult with a specialist where appropriate. The fact that an organization or Website is referred to in this work as a citation and/or a potential source of further information does not mean that the author or the publisher endorses the information the organization or Website may provide or recommendations it may make. Further, readers should be aware that Internet Websites listed in this work may have changed or disappeared between when this work was written and when it is read. No warranty may be created or extended by any promotional statements for this work. Neither the publisher nor the author shall be liable for any damages arising herefrom. 1

2009

Middle and lower cover photos courtesy of Christine and Vincent Maefsky, Poplar Hill Dairy Goat Farm, Scandia, Minnesota. Top cover photo courtesy of Russ and Rita Kellogg, Side Hill Acres, Candor, New York.

Dedication

From D.M.S. For my wife, Laurie, with abiding love and great appreciation for her support during the preparation of this work.

From M.C.S. For my parents, Randall and Lelah Cole, who have always encouraged me to “do it myself,” and my husband, Eric Smith, and our children, Kalmia and Ross, who have patiently awaited completion of this manuscript.

Contents

Preface to the First Edition Preface to the Second Edition Acknowledgments 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

Fundamentals of Goat Practice Skin Subcutaneous Swellings Musculoskeletal System Nervous System Ocular System Blood, Lymph, and Immune Systems Cardiovascular System Respiratory System Digestive System Liver and Pancreas Urinary System Reproductive System Mammary Gland and Milk Production Wasting Diseases Sudden Death Anesthesia Dehorning and Descenting Nutrition and Metabolic Diseases Herd Health Management and Preventive Medicine

ix xi xiii 3 23 61 85 163 257 275 319 339 377 501 537 571 647 691 701 709 723 733 787

Appendices A. Formulary of Some Drugs Used in Goats and Suggested Dosages B. Alternative Medicine C. Conversion Factors for Biochemistry and Hematology

807 815 823

Index

825

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Preface to the First Edition

The writing of this book was undertaken in recognition of the need for a comprehensive veterinary text addressing health and disease issues of goats raised under varying conditions around the world. The authors’ primary experiences are with intensively managed dairy and fiber goats in temperate zones. However, because most of the world’s goats live in tropical and subtropical regions, serious effort has been made to fully cover disease entities and production constraints in those areas. Much of the material presented on tropical diseases is derived from the published literature. The authors invite readers whose personal and clinical experience with these diseases in goats varies from our presentation to share their knowledge with us for the purpose of improving later editions.

We intend this book for veterinary practitioners dealing with diagnosis and treatment of individual goats as well as for those striving to improve the health and productivity of commercial herds and flocks throughout the world. Veterinarians involved in formulation of animal health policy, regulatory medicine, and livestock development should also find this information valuable. We expect this book to be useful also for academic clinicians, researchers, and veterinary students with a special interest in goats. Others who might find this book a useful reference are animal scientists, extension agents, herd managers, and hobbyists. David M. Sherman Mary C. Smith

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Preface to the Second Edition

The first edition of Goat Medicine was well received and we are pleased to have the opportunity to produce a second edition. Since the first edition appeared in 1994, the global landscape for veterinary medicine has changed dramatically. In 1996, bovine spongiform encephalopathy was recognized to be a zoonotic disease, causing variant Creutzfeldt-Jakob disease (vCJD) in humans. In 1999, West Nile virus infection reached the United States and in a short time was endemic throughout the country. In 2001, there was a major outbreak of foot and mouth disease in northern Europe, with devastating effects in the United Kingdom. That same year, the specter of bioterrorism emerged with the use of anthrax as a weapon against citizens in the United States. These events underscored the continued importance of infectious diseases in what has become an intimately interconnected, global society. These events also emphasized the need for veterinary practitioners everywhere to have knowledge of and be able to recognize diseases which traditionally have been considered exotic to their own countries. International issues influencing contemporary veterinary medicine are discussed further in David Sherman’s other textbook “Tending Animals in the Global Village”, also available from Wiley-Blackwell. Global infectious disease trends also have affected goat medicine. In 2005, the first case of bovine spongiform encephalopathy was confirmed in a goat in France. Peste des petits ruminants, a serious viral disease of goats and sheep, has extended its range from Africa through the Middle East and well into

Asia, causing widespread hardship for subsistence farmers and herders who depend on goats for their livelihoods. Repeated outbreaks of Rift Valley fever in Kenya have also taken a toll on goat populations and the people who rely on them. As such, the second edition of Goat Medicine continues to maintain a global perspective and provide information on goat diseases as they occur throughout the world. Another significant development since the publication of the first edition has been the advent of the Internet and the increased availability of information on all subjects, including the diseases of goats. Some of this information is very good and some is not so good. As in the first edition, we have strived to provide the most accurate information available on the diseases of goats, their diagnosis, treatment, and control. We have avoided whenever possible extrapolating information from other species and we continue to strive, as in the first edition, to provide definitive information that is specific to goats and supported by citations from the world’s veterinary literature as well as our own expanded experience in dealing with goat diseases in various locations around the world. As with the first edition, we intend this book primarily for veterinary practitioners but believe that academic clinicians, veterinary students, regulatory veterinarians, researchers working with goats, animal scientists, extension agents, livestock development workers, and goat owners will also find it useful. David M. Sherman, Kabul, Afghanistan Mary C. Smith, Ithaca, New York

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Acknowledgments

I would like to acknowledge with great appreciation and sincere thanks, the substantial contributions of the following colleagues: Dr. Gerrit Uilenberg, retired, for his extensive inputs on anaplasmosis, babesiosis, cowdriosis, eperythrozoonosis, theileriosis, and trypanosomosis; Dr. Peter Roeder, Taurus Animal Health, for his careful review and valuable inputs on peste des petits ruminants, rinderpest and Rift Valley fever; Dr. William G. Gavin, GTC Biotherapeutics, Framingham, Massachusetts, for his major contributions in Chapters 1 and 20 on the content related to transgenic goats; Dr. Linda Detwiler, Virginia-Maryland Regional College of Veterinary Medicine, for her detailed review and comments on bovine spongiform encephalopathy; Dr. Wilfred Goldmann, Roslin Institute and the University of Edinburgh, for his detailed review and comments on scrapie; Dr. Christophe Chartier, Agence Française de Sécurité Sanitaire des Aliments, Laboratoire d’études et de Recherches Caprines, Niort, for his comprehensive review of nematode gastroenteritis; Dr. Robin A.J. Nicholas, Veterinary Laboratories Agency (Weybridge) for his valuable inputs on mycoplasma arthritis; Dr. Etienne Thiry, University of Liege, for his most helpful review of caprine herpesvirus vulvovaginitis and balanoposthitis; and, Dr. Valgerdur Andrésdóttir, University of Iceland, for his comments on maedi-visna. I would also like to acknowledge the cooperation and inputs of Dr. Daan Dercksen of GD Animal Health Service Deventer in the Netherlands on clinical aspects of foot and mouth disease in goats; Dr. Felix Ehrensperger, University of Zürich, on Borna disease; Dr. Truske Gerdes, Onderstepoort Veterinary Institute, on diagnostic tests for Wesselsbron disease and Rift Valley fever; Dr. D.T.J. Littlewood, the Natural History Museum, London, on schistosomiasis; Dr. John C. Reagor, Texas Veterinary Medical Diagnostic Labora-

tory on hard yellow liver disease; and, Dr. Ann Wells, Springpond Holistic Animal Health, on organic livestock production. Any errors which might occur in the chapters for which these colleagues have provided inputs are solely the responsibility of the author. I would especially like to thank Ms. Suzanne Duncan, Ms. Jane Cormier and Ms. Carolyn Ziering from the Webster Veterinary Library, Cummings School of Veterinary Medicine at Tufts University for their wonderful assistance in gathering goat literature from around the world to make the completion of my chapters possible. Most of all, I owe a debt of gratitude and heartfelt thanks to my wife, Laurie Miller, without whose patience, support and encouragement, I would never have completed this task. David M. Sherman I would like to thank my colleagues at the New York State College of Veterinary Medicine, Cornell University, Ithaca, New York who have graciously reviewed manuscripts during revision of various chapters in preparation for this edition: Dr. Danny W. Scott (skin), Dr. Nita L. Irby (ocular system), Dr. Robert O. Gilbert (reproductive system), Dr. Linda Tikofsky (mammary gland and milk production), and Dr. Andrea L. Looney (anesthesia). I am also indebted to Dr. Marie S. Bulgin of the Caine Veterinary Teaching Center, University of Idaho, Caldwell, Idaho for her helpful critique of the chapter on subcutaneous swellings and Dr. Dan L. Brown of the Department of Animal Science, Cornell University, Ithaca New York and Dr. Pierre Morand-Fehr from the INRA Laboratoire de Nutrition et Alimentation, Institut National Agronomique Paris-Grignon, Paris, France for their assistance with the chapter on nutrition. Dr. Gareth F. Bath of the Faculty of Veterinary Science, University of Pretoria, xiii

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Acknowledgments

Onderstepoort, South Africa and Dr. Ray M. Kaplan from the College of Veterinary Medicine of the University of Georgia, Athens, Georgia were also very gracious about answering specific questions. The many members of the American Association of Small Ruminant Practitioners were instrumental in the creation of this text because of the questions asked and answers provided through the association’s on-line discussion list. Likewise, many goat owners and their animals contributed to my education and photo collec-

tion. I would also like to thank Susanne K. Whitaker and Michael A. Friedman of the Flower-Sprecher Veterinary Library, New York State College of Veterinary Medicine, Ithaca, New York for assistance in obtaining reference material. Finally, my husband Eric Smith deserves the greatest thanks for encouraging the writing of this manuscript and tolerating the time and attention that it has required of me. Mary C. Smith

Goat Medicine Second Edition

Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

1 Fundamentals of Goat Practice Overview 3 Distribution of Goats 3 Use of Goats 3 Current Interest in Goats 4 Distinguishing Goats from Sheep 4 Goat Behavior 5 General Characteristics 5 Ingestive and Eliminative Behavior 5 Sexual Behavior 6 Maternal Behavior 6 Handling Goats 7 Group Considerations 7 Individual Restraint 7 Administering Medications 7 Clinical Examination of Goats 9 History Taking 9 Special Considerations for Range and Pastured Goats 10 Special Considerations for Intensively Managed Goats 10

OVERVIEW Distribution of Goats According to the Food and Agriculture Organization (FAO) of the United Nations, in 2006 there were an estimated 837.2 million goats in the world, approximately 64.2% of which were in Asia, 28.8% in Africa, 4.3% in South and Central America, 2.2% in Europe, 0.3% in North America, and 0.1% in Oceania. Approximately 4.2% of the world’s goats are found in developed countries and 95.8% in developing countries (FAO 2007). Goats are highly adaptable to a broad range of climatic and geographic conditions and are more widely distributed than any other mammalian livestock. Goats are managed under every imaginable production system, including feral, transhumant, nomadic, extensive, intensive, and total confinement systems. Use of Goats Goats are exploited for diverse purposes, including meat production, cashmere and mohair fiber production, milk and cheese production, and skins for leather making. Specialty uses include brush and weed control, pack and draft use, animal experimentation (particuGoat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Special Considerations for Hobby Farms 11 Special Considerations for Organic Goat Production 11 Special Considerations for Transgenic Goats 11 Physical Examination 13 Inspection from a Distance 13 Direct Physical Examination of Individual Goats 14 General Inspection 14 Examination of the Integument 15 Examination of the Head 16 Examination of the Neck 17 Examination of the Chest 17 Examination of the Abdomen 18 Examination of the Limbs 18 Examination of the Reproductive System 18 Examination of the Environment 19 Field Necropsies and Slaughterhouse Checks 20 References 20

larly as models of ruminant digestion and human heart disease and as transgenic animals), commercial antibody production, and companionship. Goat horn and bone are sometimes used for ornamental purposes and musical instruments, while goat skins are used for drum making. Meat production is the major use of goats on a worldwide basis, particularly in Asia, Africa, the Middle East, and Latin America, and world goat meat production more than doubled between 1980 and 2000 (Morand-Fehr et al. 2004). In 2006, the seven leading goat meat producing nations in descending order were China, India, Pakistan, Sudan, Nigeria, Bangladesh, and Iran (FAO 2007a). A myriad of local and regional breeds exists around the world that are used mainly for meat. In recent years, more attention has been paid to selective breeding in goats for meat production, leading to the development of two highly efficient, purpose-bred meat goat breeds. These are the South African Boer goat (Mahan 2000) and the Kiko goat of New Zealand (Batten 1988), both of which have gained popularity in the United States, particularly in the southeast where commercial goat meat production has been expanding. 3

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The major milking breeds of goats originated primarily in Europe. These breeds include the Saanen, Toggenburg, Anglo-Nubian, and Alpine breeds. The more recently developed La Mancha breed originated in the United States. The Jamnapari and Beetal breeds of India are also important dairy breeds that are well adapted to and becoming more widely distributed in the humid tropics. The use of goat milk to manufacture cheese is an important industry in France, Spain, and other European countries. Angora goats, the source of mohair fiber, have traditionally been concentrated in a number of distinct areas, notably Turkey, where they originated, South Africa, Texas, Argentina, and some central Asian republics formerly in the USSR. Cashmere or Pashmina goats, which produce cashmere fiber, are found primarily in the mountainous regions of Central Asia, including parts of Tibet, China, Mongolia, Iran, Afghanistan, Kazakstan, Kyrgyzstan, and Tajikistan. Skins are usually a byproduct of goat slaughter for meat, but skins of certain goat breeds such as the Red Sokoto of Niger are prized for high-quality leather goods such as kidskin gloves and purses. Details of the various goat industries are beyond the scope of this veterinary text. The interested reader is referred to other sources (Gall 1981; Coop 1982; DeVendra and Burns 1983; Dubeuf et al. 2004; Morand-Fehr et al. 2004). Current Interest in Goats Worldwide interest in goats has continued to increase dramatically during the last decade. There is greater understanding of the importance of goats in agricultural systems in low-income countries. A number of humanitarian organizations, such as Heifer International and FARM-Africa, have recognized the value of using goats as a tool in rural development programs to improve the social and economic conditions of subsistence farmers and the rural poor. Methodologies for improved goat production in the tropics in support of rural development have been published (Peacock 1996). There is also increased demand for goat products in developed countries, especially goat cheese, cashmere goods, and even goat meat. Demand for goat meat in the United States has exceeded domestic supply in recent years. In 2004, the United States imported 2,400 metric tons of goat meat, mostly from Australia (Ward 2006). This expanding interest in goats has increased the demand for goat-related veterinary services in the areas of clinical medicine, research, and extension. In response to this need, interested veterinarians must familiarize themselves with goats as a species distinct from sheep and cattle, recognizing their often characteristic behavior, physiology, and response to disease.

Fortunately, a number of resources have become available to provide information in these areas. The International Goat Association (www.iga-goatworld. org/) sponsors a quadrennial international conference on goats and regularly publishes the peer-reviewed, international research journal, Small Ruminant Research, which reports research findings on all aspects of goat production including health, nutrition, genetics, physiology, and husbandry from all over the world. The American Sheep Industry Association regularly produces a similar, multidisciplinary research publication, Sheep and Goat Research Journal, which focuses specifically on small ruminant production in North America and is available on the Internet (http://www.sheepusa.org/). The American Association of Small Ruminant Practitioners (AASRP) is an excellent resource for veterinary practitioners in North America. This member organization produces a regular newsletter, Wool and Wattles, full of current, relevant information on regulatory and clinical issues as well as an e-mail discussion forum for AASRP members. The AASRP Website (www.aasrp.org/) provides links to other useful resources for goat health and production. Another useful Web-based resource for veterinarians is Consultant, which generates differential diagnoses based on clinical signs entered by the user on a species basis, with goats recognized as a distinct species. It is available on the Internet at http://www.vet.cornell.edu/ consultant/consult.asp. Finally, many state extension agencies now have much more information available on goat husbandry and production than they had in the past, and much of it accessible on the Internet. Distinguishing Goats from Sheep Source of Confusion For those whose experience with sheep and goats is limited to the common European wool breeds of sheep and the European dairy breeds of goats, the notion that individuals of the two species could be confused may seem ridiculous. However, in tropical and subtropical regions, various breeds of hair sheep are common. These breeds are often maintained in mixed flocks with local breeds of goats, and may not be readily differentiated. The following information can help in distinguishing the two species. Genetic Distinctions Goats have 60 chromosomes and sheep have 54. Though very uncommon, fertile goat-sheep hybrids have been reported. These hybrids have 57 chromosomes. The phenomenon is discussed in Chapter 13. Behavioral Distinctions A major difference between sheep and goats is feeding behavior. Sheep are grazing animals, consis-

1/Fundamentals of Goat Practice 5

tently feeding at ground level, while the goat is more of a browsing animal, readily feeding on shrubs, bushes, and trees. While both species are social, individual goats are less anxious than sheep when separated from the group. Goats are less tolerant of rain and more readily seek shelter in wet weather. The males of both species will fight, buck goats by rearing up on their hind feet and coming down forcefully to butt heads, while rams back up and then charge forward to butt heads. The anatomic structure of the horns, frontal sinuses, and neck muscles of each species is appropriate to its method of fighting, minimizing the risk of injury to combatants (Reed and Schaffer 1972). When young bucks and rams are maintained together, the rams become dominant because they preemptively strike bucks in the abdomen while the male goats are still in the act of rearing up. Whereas lambs are almost constantly at the side of ewes in early life, goats practice “lying out” or “planting” behavior with kids left in “camps” for a good part of the day while does feed. Anatomic Distinctions When wool is not obvious in sheep, other anatomic differences may be observed. Most goat breeds have an erect tail, while the tail of sheep always hangs down. The sheep has an upper lip divided by a distinct philtrum and the goat does not. Male goats, and to a lesser extent female goats, have beards, which are lacking in sheep. Goats do not have infraorbital, interdigital, or inguinal glands, while sheep do. Goats have sebaceous glands beneath the tailhead that sheep lack.

GOAT BEHAVIOR General Characteristics Goats exhibit some very distinct behavior patterns (Hafez 1975; Kilgour and Dalton 1984). Many aspects of goat behavior are conditioned by the circumstances in which the animals are kept. Many natural behavior patterns observed in free-ranging feral goats may be altered or not expressed at all under different degrees of confinement. Nevertheless, some behavior patterns are widely characteristic. Goats tend to flock together in extended family groups. They have a strong hierarchical structure in the flock or herd. Both males and females will establish social dominance in their respective groups through head to head fighting. Goats use their horns to advantage when fighting to establish their social dominance. Therefore, all goats in a group should be either horned or hornless to avoid excessive bullying by horned goats. When goats are accustomed to human contact, they will approach strangers rather than flee. When threatened or upset, they will turn and face an intruder and

make a characteristic sneezing noise. In keeping with their browsing behavior, goats orally investigate everything in their environment. This includes veterinary equipment, paperwork, clothing, and jewelry brought within their reach. When drawing blood samples or writing health papers, it is essential to keep the paperwork in a safe place or it will be eaten or destroyed. Goats will chew on pen partitions and other structures made of wood, and a large group of goats can actually devour pen walls over a period of months. They will also eat the paint off walls, so lead paint should be avoided. Goats are very agile and are excellent climbers. They are occasionally found in barn rafters, in trees, or on the hood of the veterinarian’s vehicle, if allowed access. Providing a rock pile in paddocks or pastures can foster recreation and will help to control hoof overgrowth. Goats will stand on their hind legs and lean against fences, causing considerable damage over time. Broken limbs may occur if legs are caught in the openings of chain link fences. The goats’ agility combined with their curiosity can be fatal if their heads get caught and they are strangled in fences, gates, doors, windows, or other structures. Backward curving horns contribute to this problem. Goats are notorious for successfully undoing simple gate closures and latches. This is a common occurrence in accidental grain overload cases, so goat keepers must ensure that gates are securely fastened. Goats can easily jump fences designed for sheep and also will dig under fences that do not closely skirt the ground. Goat fencing should never have interior sloping support posts because goats will use them to climb out of the enclosure. Goats ignore barbed wire and therefore it should not be used because it can inflict serious damage. Thus, electric fencing has become popular for goat operations because the animals quickly learn to respect it. Ingestive and Eliminative Behavior A key to the adaptability of goats worldwide is their efficient browsing ability. This same efficiency, however, has given the goat notoriety as an important cause of desertification in some regions of the world. The reputation is not always deserved because overgrazing by numerous livestock species may be at fault, but only the goats are left surviving when vegetation is almost gone (Dunbar 1984). Goats may climb into trees to reach food when it is scarce. If permitted, they can girdle the bark from trees, thus killing them. Goats are used to clear brush to reclaim pasture land for sheep and cattle. When run simultaneously with sheep and cattle, they may improve pasture quality for these other species by contributing manure for fertilization, removing toxic plants such as oak to which they are more resistant than the other ruminant species, and

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Goat Medicine

eliminating brush to allow more sunlight for improved grass growth (Ward 2006). Owners feeding goats in confinement often complain that the animals waste a good deal of hay, particularly leaving behind the nutritious leafy parts of good legume hay. This tendency can be countered to some extent by feeder designs that inhibit the goat from pulling hay out of the feeder and dropping it on the floor. Goats are also finicky about contaminated feed and water supplies and may refuse water containing fecal pellets or hay and grain in wet troughs that smell moldy. In free-ranging feral and Angora goats, approximately 30% of the day is spent in feeding, usually divided into sunrise, midday, and sunset periods. Onethird of this is grazing time, two-thirds browsing. About half the day is spent resting, 10% ruminating, and 12% traveling (Askins and Turner 1972; Kilgour and Ross 1980). In contrast, intensively managed Saanen milking goats eat for 20% of the day, ruminate 25%, travel 20%, sleep 11%, rest recumbent 14%, and rest standing approximately 8% of each day. They defecate on average 11.2 times and urinate 8.3 times daily (Pu, personal communication 1990). Goats raise their tails to defecate and normally produce pelleted feces. Female goats squat to urinate. During the non-breeding season, males urinate on the ground with little or no extension of the penis beyond the prepuce. However, during the breeding season, the pattern of urination is markedly different and associated with sexual behavior as discussed below. Goats cannot be prompted easily to urinate by holding off their nares, as is done with sheep. This makes simple collection of a urine specimen problematic. Sexual Behavior In tropical and subtropical regions, estrus generally occurs year-round while in temperate regions goats are seasonally polyestrus, with breeding season triggered by decreasing day length. Breed factors may also play a role in this pattern because relocation of some indigenous breeds to new climatic zones does not result in a change of estrus pattern. Specific information on the frequency, signs, and patterns of estrus are provided in Chapter 13. Male sexual behavior reflects the pattern seen in does. Libido and sperm quality may be depressed during anestrous seasons. However, if females are brought into estrus by hormonal manipulation, bucks quickly respond out of season. The obnoxious behavior and strong odor of bucks during breeding season are notorious. At least two factors contribute to buck odor. First, the aroused buck repeatedly urinates on himself, soaking his head, neck, and forequarters. He will sometimes take his erect penis into his mouth. Afterwards, the buck may yawn

and demonstrate the flehmen reaction, curling his upper lip. Second, the buck possesses sebaceous scent glands on his head, caudomedial to the base of the horn, which during active rutting produce an odiferous compound identified as 6-trans nonenal (Smith et al. 1984). This compound may also be released from the sebaceous gland under the tail. It acts as a potent pheromone and the odor alone can induce estrus in the doe. Bucks show active fighting behavior at the beginning of and during the breeding season to establish dominance. Veterinarians and owners should exercise caution when working around sexually active bucks. A full grown buck striking from the standing position can produce serious or fatal injury. For this reason, bucks of different sizes in confinement operations should be segregated so that smaller, younger bucks are not injured or killed. Do not turn your back to an unrestrained buck! During courtship, the buck will sniff the urine of does and follow with the flehmen response. To display to does, a buck holds his head erect and high or he lowers his extended head and neck to the ground. He may also kick out at the doe with an extended forelimb, but rarely actually strike her. Courtship is accompanied by much frenzied vocalizing and flicking the tongue in and out. Sexually active bucks commonly lose weight during the breeding season. Maternal Behavior Free-ranging goats separate from the herd and hide to kid. Confined goats may attempt to conceal themselves. As parturition approaches, does become restless and paw at the ground, making rudimentary efforts to “nest build.” Details of parturition and the recognition of dystocia are discussed in Chapter 13. Following parturition, the doe actively licks the kids, and this is considered to be critical to successful bonding. If does are frightened or disturbed at this point, or if licking is delayed longer than one hour, bonding may be impaired and kids may be abandoned or mothered less effectively. Kids are precocial, standing and seeking the hairless udder shortly after birth. In free-ranging herds, there is a “lying-out” period of several days to several weeks when does may leave kids in sheltered areas for periods of two to eight hours while they feed. Does must be familiar with the geography to return successfully to their kids. Therefore, it is not advisable to move does to new grazing areas immediately before kidding. Does will respond to alarm calls from their distant kids and return to defend them if bonding is strong. Kids gradually begin to follow their dams, learning to browse and graze. The infrequent nursing pattern of young kids makes the goat adaptable to the twice-aday feeding regimens that are often practiced under

1/Fundamentals of Goat Practice 7

intensive management. If given boxes to hide in, kids raised in confinement will use them for the first week, coming out only to suckle the dam.

HANDLING GOATS Group Considerations Goats are highly adaptable and trainable animals. Feral goats captured in Australia and New Zealand may become used to handling in confinement within weeks, although if frightened suddenly they can clear sheep fences with ease. Dairy goats are readily trained into milking routines involving parlors and machine milking. Although Angora kids may scream the first time they are sheared, they get used to the procedure. Goats used to human contact can be mustered by calling. Moving less tame goats on open range is similar to moving sheep. Dogs can be used, but they must be well trained. The flight distance of feral goats is eight to ten meters. Goats are more likely to turn and fight than sheep if provoked by a dog. Animals that break away from the group should be left to follow along rather than chased. The presence of sheep with the goats can actually facilitate flocking and driving, although on hills, goats tend to move upward and sheep downward. When collected in yards, anxious goats may pile up in a corner and some may suffocate, so they should be divided into small groups. When possible goats should be allowed to spend 24 hours in a handling facility before they are worked so they are more comfortable with their surroundings. Horned goats may be very wary of entering narrow races and gates. When working horned goats in close quarters, the danger of face and eye injuries to handlers is high, and protective eye wear should be used. Individual Restraint Tame goats will stop when caught by the gastrocnemius tendon. However, if a frightened or wary goat is actively fleeing or struggling, capture by the limb can lead to serious dislocations of joints or fractures of long bones, particularly in young animals. It is preferable to catch animals by hooking an arm around the neck or torso or by grabbing the collar, horns, beard, or, less desirably, the ears. Goats used to human contact can be trained to lead. Goats that pull strongly against neck chains will commonly cough and, rarely, cause trauma to the trachea. Goats used to handling are usually easily restrained for examination, administration of medication, or routine sample collection. Such goats can be haltered or lead shanks can be tied to neck straps and then secured. Uncooperative goats can be straddled over the withers by a handler with the goat’s hind end backed into a corner and the head held firmly by the

handler (Figure 1.1). If a goat is horned, the horns should be held when restraining goats in close quarters to avoid injury to the handler. Bearded goats can be led by the beard and non-bearded goats by the ears, though some owners may object to the latter practice. For smaller, uncooperative goats, flipping the animal into lateral recumbency and then placing the handler’s knee on the goat’s neck may provide effective restraint. Goats do not become passive when tipped up on the rump in the manner used for sheep, so this method of restraint is less useful; this is a problem regarding shearing. A modification of the technique to avoid struggling is to first tip up the goat, and then allow the head to fall backward between the handler’s thighs so that the goat’s back is resting on the handler’s shins. This redistributes the goat’s weight from the bony rump to the back, making it more comfortable for the goat. Tipping up the goat is useful for examining the prepuce and penis of male goats suspected of urolithiasis. In this case, the weight of the goat’s upper body needs to be shifted forward to facilitate extension of the penis. Foot trimming is most easily carried out by raising the distal limbs of the standing goat. Administering Medications Oral Medications Mass medication of feed and water is no more reliable in goats than in other species, because sick animals are likely to have reduced feed and possibly water intake. In addition, goats, being fastidious about water supplies, may detect a change in the odor or flavor of the water and refuse to drink it. When drenching individual goats, the head should be held horizontally and not tilted up, reducing the chances of aspiration pneumonia. The drenching gun should be inserted at the commissure of the lips and the nostrils held off while the medication is quickly dispensed. To successfully administer boluses with a balling gun, the gun must be carefully worked over the base of the tongue before dispensing the bolus or the pill will be chewed and spit out. Put the gun into the mouth at the commissure of the lips to facilitate this process. Do not force the gun into the pharynx or traumatic injury can occur. Balling and drenching guns should be examined before use to ensure that they do not have sharp defects that could injure the goats. Passing a stomach tube in goats via the mouth is not particularly difficult if proper restraint and a suitable speculum are available. Commercially available sheep speculums work well with goats, as does a block of wood with a circular hole cut through it. Small diameter, well lubricated tubes can be passed through the nose to the stomach.

8

Goat Medicine

Figure 1.1. Useful restraint methods for intravenous blood sampling or medicine administration via the jugular vein of a goat. Backing the goat into a corner, as shown, improves control. In Figure. 1.1a, the goat is restrained so that an assistant, kneeling in front of the goat, can easily take the sample or give the medicine. In Figure. 1.1b, the goat is positioned with the head tucked under the handler’s arm so that sampling or medicine administration can be accomplished by the handler alone. (Illustrations by Mr. Nadir Kohzad.)

Injections Mass medication or vaccination using a common needle has long been practiced by some farmers and veterinarians. In the case of goats, as with other species, it is time to rethink this practice, particularly in light of the growing importance of caprine arthritis encephalitis virus (CAEV) in goats. This retrovirus may be transmissible by blood-contaminated needles. Certainly, in herds where the virus is known to exist, or attempts are under way to control it, it would be counterproductive and negligent to use common needles. Additional discussion of this important caprine disease is found in Chapters 4 and 5. Another reason to use individual needles in conjunction with other good hygienic practices during vaccination is the tendency for goats to develop large swellings and even abscesses at injection sites after vaccination with clostridial, chlamydial, and paratuberculosis vaccines. If the veterinarian’s technique is exemplary, he or she is unlikely to be held accountable for any problems that develop later.

If skins are marketed from a goat herd, the veterinarian should avoid injections of any kind in regions of the body that become part of the marketed skin, because defects can occur secondary to injection site reactions and devalue the skin. Therefore, the back and upper flanks should be avoided even though they are often convenient. Intramuscular injections can cause difficulties in goats. The preferred site is in the neck, in a triangular region bounded by the vertebral column ventrally, the nuchal ligament dorsally, and the shoulder caudally. The triceps can also be used. If skin quality is not a consideration, the longissimus muscles over the back in the lumbar region may also be used. In all cases, the volume of drug administered in one site should not be greater than 5 ml. Needles should be 2 to 3 cm long and no larger than 18-gauge unless the medication is highly viscous. Shorter needles should be used for young kids. The thigh muscles should be avoided as a site of intramuscular injection in adults and especially young

1/Fundamentals of Goat Practice 9

goats. The muscle mass is small compared to other ruminants, and sciatic nerve damage is not uncommon. Owners should be counseled against using this site. Even when the nerve is not damaged, marked lameness can occur when irritating drugs such as oxytetracycline are given in the leg. Permanent muscle damage can also occur that devalues the carcasses of meat goats. Subcutaneous injections are commonly given in the neck in the same region described for intramuscular injections, or on the chest wall about 5 cm behind the point of the elbow. Injections ahead of the shoulder should be avoided in show goats, because local reactions near the superficial cervical (prescapular) lymph node may be confused with caseous lymphadenitis. Needles should be 18- to 20-gauge. The risk of accidental intramuscular injection may be increased if long needles are used. Intravenous drugs are given via the jugular vein generally using 2 to 3 cm long needles of 18- or 20gauge. Blood samples can be taken from the jugular vein using an 18-gauge needle. Intradermal injections are given using 26-gauge, 1-cm long tuberculin needles. Intraperitoneal injections are rarely used except to treat neonates for hypoglycemia with glucose solutions or navel infections with aqueous based antibiotics. With the kid held hanging by the front legs, an 18- or 20-gauge needle is inserted perpendicular to the skin about 1 cm to the left of the navel no deeper than 1 cm. When intramammary infusions are given, the teat should first be cleaned and swabbed with alcohol. As in cattle, single use teat cannulae should be used for each infusion with the cannula inserted into the teat only enough to gain entry into the teat cistern. For very small teat openings, sterile tomcat catheters can be used to infuse the teat.

CLINICAL EXAMINATION OF GOATS A complete clinical examination consists of three major elements: history taking, physical examination, and inspection of the environment. Many diseases seen in individual goats are likely to represent potential herd problems; therefore, prompt diagnosis of clinical cases is essential so that, in addition to therapy, appropriate preventive measures can be introduced into the overall management program. In many caprine diseases, subclinical cases often exist in addition to the obvious clinical ones, and additional diagnostic testing may be required to identify them. The existence of subclinical infections and carrier states is a troublesome one for veterinarians performing prepurchase health examinations or writing health certificates for exportation or interstate travel. A list of such caprine diseases that the veterinarian must be aware of is given in Table 1.1. History Taking Very few diseases or health-related problems are randomly distributed in a flock or herd of goats; rather, they are concentrated in specific groups, usually by sex, function, production status, or age. Always establish early on what age, sex, breed, or group of goats is dying, showing signs of illness, aborting, or showing decreased productivity. If it is a mixed farm operation, the number of other types of livestock and their degree of contact with goats should be ascertained. Detailed history should include a determination of the total flock or herd population and estimation of its breakdown by sex, age, breed, and pregnancy status. Having determined the total animal population, the population at risk, and the number of animals affected and dying, it is possible to determine rates of disease occurrence and case fatality rates. By counting cases,

Table 1.1. Goat diseases characterized by chronic infection or a carrier state. Viral/prion

Rickettsial

Bacterial

Protozoal

Unknown

Caprine arthritis encephalitis Foot and mouth disease Scrapie

Chlamydiosis Coxiellosis (Q fever)

Caseous lymphadenitis Paratuberculosis Salmonellosis Listeriosis Brucellosis Melioidosis Tuberculosis Mycoplasmosis Staphylococcal mastitis

Toxoplasmosis

Udder warts in white goats

10 Goat Medicine

the investigator is also in a better position to determine the actual significance of a problem as compared to the farmer’s perception of it. In some cases, the loss of a few animals may be insignificant compared to a more serious unrecognized problem such as endoparasitism or ectoparasitism. Such an epidemiologically based history should aim to identify not only specific problems but also specific risk factors that appear to be associated with mortality, morbidity, or suboptimal performance. For example, when a primary complaint of kids developing diarrhea after weaning suggests coccidiosis, additional questions concerning the segregation of kids from adults, the manner that kids are fed, the design of feeders, the frequency and manner of barn cleaning, and details on the use of coccidiostats are necessary. In such cases, modification of management practices may halt the spread of disease. Temporal relationships are important to note. Some diseases may occur seasonally, in association with abrupt weather changes, or in relation to specific events such as breeding, pregnancy, shearing, parturition, and lactation. For example, an unexpected cold snap or heavy rain right after shearing of Angora goats can increase pneumonia, abortion, and death rates, particularly if adequate shelter and supplemental feed have not been provided. Localization of death or disease to specific areas on the premises is helpful. For example, if losses are seen only in certain areas of the farm, specific pastures, or particular barns, then suspicion of poisoning is increased. Other important aspects of the history include questions pertaining to the actual ration being fed and its consumption, methods of feeding, changes in feeding, access to grazing, and water supply type and water availability. If management interventions or preventive health procedures have been undertaken recently, they should be identified. Shearing, drenching, dehorning, spraying or dipping, castration, or vaccination can be associated with increases in morbidity and mortality. When range animals are mobbed for such procedures, sudden close confinement, temporary feed deprivation, and abrupt weather changes can predispose to outbreaks of conditions such as abortion, coccidiosis, salmonellosis, hypocalcemia, or starvation as a result of mismothering. When drugs or vaccines are used, the products and dosages, number of treatments, and method of administration should be determined, particularly because many goat farmers traditionally obtain their drugs and biologicals from nonveterinary sources. If animals have been transported recently, dates, origins, means of transportation, and quarantine times should be determined. Information should also be col-

lected on visits to shows or fairs and on the origin of purchased animals, be it other farms, stockyards, or specialized goat sales. If animals have come from out of state, the relevant health certificates should be examined and the disease situation in the state of origin reviewed. Finally, the reliability of information obtained should be checked with the actual goat keepers if the owner is not involved with day-to-day management decisions. If the veterinarian has prior knowledge of the local disease patterns in goats, such knowledge should not be used to make hasty and possibly incorrect judgments. Special Considerations for Range and Pastured Goats Extensively managed animals may not be closely observed, and histories can be sketchy. With large flocks, it should be determined if the animals are managed as a single flock or in smaller, self-contained units. The seasonal pattern of grazing and the length of grazing periods should be noted. Pasture composition, seasonal stocking rates per acre, the degree of pasture subdivision, and length of resting periods between grazing should be established. Note if supplemental feeding is practiced and the types of feed used. This may be important in terms of meeting specific nutritional needs, and, in the case of silage, may be associated with diseases such as listeriosis or rumen acidosis. Inquiries should also be made about whether crops are fed or grazed, the type and stage of growth, and whether there is a recent history of fertilizer or herbicide application. Knowledge of local trace element deficiencies or excesses may be helpful. The type of grazing, whether set stocked or rotational, may be relevant to some disease outbreaks, particularly to gastrointestinal helminthiasis. The presence of other livestock species and feral, predatory, or scavenging animals or birds should be established if relevant to the problem under investigation. Special Considerations for Intensively Managed Goats A complete history can usually be obtained from the owner or herdsman of intensively managed goats. The patterns of disease are also likely to be different, with pneumonia and enteric diseases of young goats assuming much greater significance than the foot rot, helminthiasis, predation, or toxic plant problems more often seen under grazing systems. Feed composition and intake are more regulated but the veterinarian must inquire about episodes of sudden changes, excesses, or deprivations in the feed and water supplies. Under close quarters, the movement, mixing, or introduction of new animals is more likely to cause an outbreak of disease. Kidding is often assisted in inten-

1/Fundamentals of Goat Practice 11

sively managed operations, and artificial kid rearing methods are commonly used. These procedures should be carefully reviewed when morbidity and mortality are concentrated in young kids. Weather, per se, should not adversely affect intensively managed animals. However, extremes in temperature may tax the ventilatory capacity of confinement buildings and extremely cold weather may freeze water supplies or incapacitate mechanized feeding equipment. Answers to questions about changes in dairy herd milking procedures or personnel may help to explain mastitis problems. Special Considerations for Hobby Farms Because hobbyists often have little previous agricultural or livestock experience, it might be helpful to practitioners to gauge the owners’ knowledge and attitudes regarding basic animal husbandry before history taking. Some fundamental misunderstandings about the care and management of goats may be revealed, such as non-recognition of basic ruminant physiology and the need for roughage in the diet. In other situations, owners may know about basic husbandry and disease problems, but may have seemingly unorthodox ideas about management and treatment. A good deal of tact may be required to obtain a useful history and prescribe appropriate therapy while not offending the hobbyist’s sensibilities. In addition, hobby farmers often perceive goats more as companion animals than as livestock production units. While they may seek the expertise of a livestock clinician, they often expect the “bedside manner” of the companion animal practitioner. Therefore, the veterinarian who appears insensitive to the client’s emotions or indifferent to pain of the goat or who emphasizes only the economic value of the animal may not be called to the farm again. Special Considerations for Organic Goat Production Consumer interest in organically produced food has grown considerably over the past twenty years or so and producers have responded by producing and marketing an expanding variety of foodstuffs certified as organic. Increasingly, this includes foods of animal origin. Goat owners may choose to raise their goats under organic conditions. Veterinary practitioners with such clients need to be aware of and familiar with the constraints on conventional therapy that are associated with organic livestock production, which is now strictly regulated by law (Karreman 2006). In the United States, the Organic Food Production Act (OFPA) was signed into law in 1990, creating the framework for regulation and certification of organically produced foods of plant and animal origin. The OFPA created the National Organic Standards Board (NOSB) which reviews materials for consideration as

acceptable for use in organic food production, including veterinary inputs used to maintain animal health. As a general rule, all natural materials are allowed for use in organic agriculture, unless specifically prohibited, while all synthetic materials are prohibited unless specifically permitted, following a successful petition process to the NOSB. The specific regulations of the National Organic Program are found in the United States Code of Federal Regulations at 7 CFR 205. These regulations became effective in 2002. Vaccination is promoted as an organic livestock health care practice under 7 CFR 205, but the use of antibiotics and most anthelmintics is prohibited. Veterinarians must approach therapeutic interventions in organically raised animals differently than in conventionally raised animals, relying heavily on so-called natural treatments, including botanicals, acupuncture, homeopathy, etc. The standards of livestock health care practice which must be observed under the OFPA are given in 7 CFR 205.238. Veterinarians should be aware, however, that 7 CFR 205.238 considers the welfare of organically raised livestock by stipulating that an organic livestock producer may “not withhold medical treatment from a sick animal in an effort to preserve its organic status. All appropriate medications must be used to restore an animal to health when methods acceptable to organic production fail. Livestock treated with a prohibited substance must be clearly identified and shall not be sold, labeled, or represented as organically produced.” The synthetic substances allowed for use in organic livestock production are found in 7 CFR 205.603. The full text of the regulations can be found at www.ams.usda.gov/nop/ NOP/standards/FullRegTextOnly.html. In Europe, organic production is regulated throughout the European Union (EU). EU regulation number 1804/99, which became effective in 2000, sets forth the rules for organic livestock production including animal health and veterinary interventions. All EU member states at a minimum comply with these rules, but some individual countries have included additional rules of their own. Specifications of the European and U.S. regulations have been compared (Nardone et al. 2004). Special Considerations for Transgenic Goats Production of transgenic animals using microinjection or nuclear transfer and the propagation of desirable animals using cloning are no longer just scientific research endeavors. They have become established production systems for the propagation and management of transgenic goats. It behooves veterinarians with active goat practice to be familiar with the basic techniques and health issues associated with transgenic goat production. Transgenic technology began in 1980 when the first transgenic mouse was developed (Gordon et al. 1980).

12 Goat Medicine

The first transgenic goat was developed in 1989, producing rhtPA (recombinant human tissue plasminogen activator) in the milk (Ebert et al. 1991) as a potential human therapeutic agent. Since then, the field has markedly expanded with transgenic animals becoming commonplace within many programs and facilities. The applications for transgenic animals are considerable and include not only the investigation of gene function but also the development of animal models, increased disease resistance through either transgene insertion or knock-out techniques, and production of recombinant, biopharmaceutical proteins in a number of biological fluids such as milk, blood, urine, and semen (Nieman and Kues 2003). In fact, distribution of the first transgenically derived human therapeutic recombinant protein from goat milk (ATryn®) was approved by the European Agency for the Evaluation of Medicinal Products in 2006 and by the Food and Drug Administration in the United States in 2009. The two main techniques employed for making transgenic animals are microinjection and nuclear transfer (cloning). While microinjection was the first technology to be used in making large transgenic animals (Hammer et al. 1985), and specifically the goat (Gavin 1996), the process is inefficient with only a small percentage of the resulting animals being transgenic. Large animal nuclear transfer (Campbell et al. 1996; Wilmut et al. 1997) was developed later and provides for a near 100% transgenic rate when compared to microinjection. The cloning of the first transgenic goat soon followed (Baguisi et al. 1999; Keefer et al. 2001). There are other techniques for producing transgenic animals such as retroviral gene transfer and artificial chromosome insertion. However, these techniques have not been used yet in goats and are not mentioned further. Most transgenic goats are maintained in USDAAPHIS-AC Licensed Research Facilities. Under the auspices of the Animal Welfare Act (AWA), these licensed facilities must maintain strict adherence to rules and regulations specifically governing animal care, health, and welfare (housing, lighting, feeding, veterinary care, and environmental enrichment at a minimum). Depending upon the type of research and the funding source, the National Institutes of Health (NIH) may also be involved through their Office of Laboratory Animal Welfare (OLAW) as government funding brings along its own slightly different set of rules and regulations for animals used in a research setting. A growing number of institutions are also striving for accreditation by the Association for the Assessment and Accreditation of Laboratory Animal Care, International (AAALAC-Int.), considered by many to set the gold standard for animal care in licensed research programs and facilities. Lastly, depending upon the intended use of any tissues/fluids

from the transgenic animal, the FDA may also have regulatory oversight and impose its own set of rules and regulations. The use of microinjection to produce a transgenic animal involves microinjection of the transgene into the pronucleus of a fertilized, one-cell embryo and then the transfer of surviving embryos to a surrogate mother. One of the first areas for possible concern, and for which observation and monitoring are appropriate, is the physical/mechanical effects on the nucleus/gene due to the actual microinjection process at the one-cell stage. If any negative impacts occur or gene functions are altered or impaired, one may see outcomes ranging from decreased pregnancy rates from transferred embryos to increased pregnancy loss, late term abortions, or possible physiological abnormalities at birth with clinical sequelae. However, years of experience now indicate that these phenomena, while possible, occurs at a very low incidence. Regardless of the technique used to produce a transgenic goat, another possible concern involves endogenous gene function and potential transgene insertional site effects. The gene of interest inserts randomly into the genome following transgene introduction. Hence, there is a chance that an endogenous gene could be negatively impacted, leading to potential adverse physiological effects and a transgenic goat presenting with clinical signs of abnormal physiology or health. Therefore, appropriate post-parturitional monitoring of animal health is warranted for any transgenic founder animal. Introduction of a transgene produces a goat that is hemizygous for that given transgene. Subsequent breeding within a lineage may be aimed at achieving a homozygous state for the transgene. Possible concerns may arise through this approach. First, inbreeding of related goats is the primary route to achieving a homozygous animal. Therefore, inbreeding coefficients need to be considered and animals need to be monitored for ill effects from this relatedness and for possible impacts on overall health and ability to thrive. Second, achieving a homozygous state may bring to light an insertional gene effect since both copies of an endogenous gene may now be affected thereby causing physiological or clinical issues that were not seen in the hemizygous state. Again, appropriate monitoring of animal health is warranted for the first homozygous animals produced. Lastly, the potential exists that breeding for the production of a transgenic homozygous animal will reveal a lethal outcome. A lethality issue may be suspected when: breedings of two hemizygous animals produce no detectable pregnancies; pregnancies do not hold to term with either resorptions or abortions; or, offspring succumb soon after birth. Thus, production of a homozygous transgenic animal may not always be possible and close animal

1/Fundamentals of Goat Practice 13

health monitoring is warranted when homozygosity is pursued. One additional set of concerns related to transgene effects is the possibility of systemic circulation of the recombinant protein being expressed and the potential health impacts arising from expression of pharmacologically active molecules. Depending on the tissue or fluid where the recombinant protein may be directed for expression (e.g., milk, blood, urine, semen, etc.), one must be vigilant for systemic effects as the protein usually will be found systemically due to leaky vasculature and normal lymphatic drainage. Therefore, the biological nature and function of the recombinant protein being introduced must be known so that any effects which may be exerted can be anticipated and recognized. Consideration must also be given to potential adverse health impacts if this is a new gene and novel protein not normally physiologically found in the genome or animal. Lastly, the quantity of the recombinant protein that is expressed and then found systemically in the transgenic animal must be considered. Even if the target protein is endogenous to the animal, it may be found at significantly higher levels than normal and may cause physiological effects that alter normal homeostasis. As with any traditional goat agricultural production operation for meat, milk, or fiber, optimizing health and product output starts with a sound nutritional program. Relative to transgenic production, nutritional programs should consider the nature of the recombinant protein to be produced. Specifically, if the recombinant protein is novel to the physiological output of the goat’s normal cellular machinery, or if quantities are above what is normally produced in vivo, then one may need to augment the diet. This modified or fortified diet may need to contain increased levels of vitamins, minerals, or specific amino acids. One should understand the normal cellular machinery and biochemical pathways involved in protein production to know if or what supplementation may be appropriate or necessary. With the development of cloning technology, nuclear transfer has become the preferred method for producing transgenic goats and has greatly improved the overall efficiency of the process. However, the use of nuclear transfer has added some additional health concerns in a small percentage of animals. Nuclear transfer starts by removing the maternal DNA from an unfertilized oocyte through enucleation. A full complement of genetic material is subsequently replaced by addition of a somatic cell (e.g. fetal or adult skin fibroblast cell) through a process termed reconstruction. Thereafter, in vitro techniques are used to fuse the oocyte and somatic cell and activate the couplet to begin dividing. Following a brief in vitro culture period, these newly developed cloned embryos

are then transferred to recipient goats using traditional embryo transfer techniques. With nuclear transfer, a decreased in utero fetal survival rate can be seen very early in pregnancy and has been well documented in many species (Campbell et al. 1996; Wilmut et al. 1997; Baguisi et al. 1999). This inability to thrive may be associated with inappropriate or inadequate reprogramming (Dean et al. 2001) of the nuclear/genetic material of the donor cell line or karyoplast and has been postulated to be at the level of the DNA (e.g., methylation pattern). An altered inheritance of cellular mitochondria (Wells 2005) has also been shown to occur in cloned embryos, adding to the possible causes for some of the abnormalities in homeostasis. Both of these phenomena may be directly linked to the small percentage of physiological problems seen in utero for some cloned animals such as abnormal placentation and/or organogenesis (Farin et al. 2006; Loi et al. 2006; Fletcher et al. 2007). Abnormal placentation can also lead to abnormal uterine fluid homeostasis and fluid retention in does carrying cloned embryos, which may warrant close clinical monitoring or intervention where appropriate. Other possible outcomes of abnormal placentation include: a tendency toward decreased pregnancy rates for animals receiving cloned embryos, an increased in utero loss rate through resorption, or an increased level of abortions if there is late term fetal loss. The potential abnormal physiology with or without clinical presentations may continue after birth and into the neonatal and early prepuberal stages (Hill et al. 1999). Documented abnormalities in a few large animal species have been shown at the level of the renal, cardiac, respiratory, hepatic, hematopoietic, and immune systems. However, if the small percentage of animals, including goats, that present with these abnormal physiological entities can be clinically supported over time, as the animals grow, many of these abnormalities resolve and they can lead normal and healthy lives (Chavatte-Palmer et al. 2002). The vast majority of transgenic and cloned animals are normal and healthy (Walsh et al. 2003; Enright et al. 2002; Tayfur Tecirlioglu et al. 2006) and subsequent generations of animals produced from first generation clones have not shown any of the health related issues seen in a small percentage of original clones (Wells 2005). In fact, passage through the germ line has been reported to reverse any abnormal patterns detected at the DNA level in first generation clones (Wells 2005).

PHYSICAL EXAMINATION Inspection from a Distance It is often useful diagnostically to observe a group of goats from a distance prior to disturbing them for “hands-on” examination. This is especially true at the

14 Goat Medicine

time of the initial visit to identify the existence of common problems in the herd or flock. The animals should be observed at rest, while eating or drinking, and during spontaneous and forced movement. General impressions of body condition, mental attitude, and social hierarchy may be acquired and abnormal behaviors characteristic of certain diseases may be noted. Estimated prevalence of common disease problems such as kid pneumonia, diarrhea, and pinkeye can be roughly assessed, respectively, by counting coughers, stained hindquarters, and runny eyes. Other specific observations that might suggest commonly seen disease problems in goats are briefly discussed below. This is for illustration and is not meant to be comprehensive. Individual goats that appear listless, separate themselves from the herd, or are not actively feeding when others are should be noted and later caught for careful examination as should animals in very poor body condition. Reluctance to feed may be due to a wide range of systemic diseases or localized conditions such as dental or pharyngeal problems, or the result of inadequate bunk space or bullying by dominant does. Latent signs of respiratory disease or anemia associated with parasitism can be brought out by forced movement of a flock. Anemia is manifested by rapid fatigue, increased heart and respiratory rates, and sometimes collapse. Increased respiratory rate, dyspnea, and coughing indicate respiratory problems. Signs of skin irritation or pruritus manifested as hair loss, fleece biting, or rubbing against fences or other solid objects usually suggest ectoparasitism, though scrapie, pseudorabies, and migrating Parelaphostrongylus tenuis are other possibilities. Goats scratching at their ears with their hind limbs or shaking their heads vigorously probably have ear mites. Goats observed resting or walking on their knees often have chronic CAEV infection or sore feet. Any animals with abnormalities of gait or lameness after forced exercise should be carefully examined for evidence of arthritis, fractures, laminitis, and lesions of foot rot or foot scald. A variety of clinical signs may be observed in goats with neurologic disease. Among the more common are ataxia, posterior paresis, circling, depression, head pressing, unilateral facial paralysis, and blindness. Details on carrying out a neurologic examination and differential diagnosis for signs of neurologic disease are provided in Chapter 5. Straining while attempting to urinate, particularly in bucks and wethers, should suggest the possibility of urolithiasis or posthitis. Cutaneous swellings or discharges may be observed. Draining abscesses associated with lymph nodes are

highly suggestive of caseous lymphadenitis in the flock or herd. A high rate of subcutaneous swellings is often associated with injection site reactions in goats in response to certain adjuvanted vaccines or bacterins or when aseptic injection techniques are not followed. When kids are left with does, careful observation of suckling behavior can indicate kids that are not successfully nursing. Their does should be examined particularly for signs of mastitis or other udder problems. Direct Physical Examination of Individual Goats A topographical approach to physical examination is presented here. Because of the small size of goats, rectal palpation is limited to insertion of a finger into the rectum to assess the pelvic structures and to determine the presence and character of feces. When economics permit, physical examination findings should be supplemented through use of appropriate imaging techniques, diagnostic procedures, and laboratory tests. When numerous individuals in a herd or flock show signs of disease, field necropsy examination may be the most effective way to establish or confirm a diagnosis. General Inspection Body condition, mental attitude, and the status of the superficial lymph nodes should be noted. The temperature, pulse, and respiration should be recorded. Fleece in Angora goats makes visual assessment of body condition difficult. Digital palpation of the ribs, spinous and transverse processes of the vertebrae, and the loin muscle may be necessary to evaluate condition. A word of caution about condition scoring in goats: scoring systems derived for sheep are not directly applicable to goats because goats as a species tend to deposit stored fat intra-abdominally rather than subcutaneously. Scoring systems for dairy goats combine palpation of the sternal and lumbar regions and are discussed in Chapter 19. In general, any palpable back fat in a dairy goat would classify her as obese. A scoring system applied to the Small East African goat in Zimbabwe showed a good correlation between a backbone condition score and changes in bodyweight (bw), with a 1-point change in condition score representing an average change of 12% in bw (Honhold et al. 1989). Normally goats have an alert, attentive, and inquisitive mental attitude. A depressed attitude is characterized by dullness, separation from the flock, and indifference to handling. Depression is present in a wide variety of septic and toxemic conditions but is a particularly prominent sign in pregnancy toxemia and listeriosis. An anxious or apprehensive state is often associated with urethral obstruction in males, sudden

1/Fundamentals of Goat Practice 15

blindness as may occur in polioencephalomalacia, or with persistent irritations such as flies and nasal myiasis. An attitude of extreme excitation is most often associated with neurological diseases such as tetanus and meningitis that may be accompanied by muscular rigidity, or encephalitic conditions such as pseudorabies and rabies. Digital palpation of all superficial lymph nodes should always be a part of the physical exam because of the clinical importance of caseous lymphadenitis in goats. The mandibular, parotid, retropharyngeal, superficial cervical (prescapular), subiliac (prefemoral), and superficial inguinal (supramammary) lymph nodes should be inspected. Normal sized nodes may not be palpable in some of these locations but affected nodes should be readily evident. Any other swellings on the body surface should be noted. Temperature, pulse, and respiration should be measured when the animal is calm because the activity of catching the animal for examination may elevate all three parameters. When taking the goat’s rectal temperature, an accumulation of brown, waxy material may be noted near the anus. This is the normal secretion of the sebaceous gland located below the base of the tail (Figure 1.2). The normal body temperature of goats is usually reported in the range of 38.6° to 40°C (101.5° to 104°F). However, the body temperature of a normal Angora goat with a full fleece on a hot, humid day can reach 40.3°C (104.5°F) or higher, and goats of lighter bodyweight are more likely to have higher temperatures when exposed to sun than bigger goats (McGregor 1985). To accurately assess the febrile state of the patient, it is useful to record body temperatures in apparently normal herd mates. The pulse can be measured by stethoscope over the heart or by digital palpation of the femoral artery. Normal pulse rate ranges from 70 to 90 beats per minute (bpm) in resting adults, but can be double that in young, active kids. Fetal heart rates up to 180 bpm have been recorded by ultrasound. It may be useful to assess respiratory rate both at rest and after exercise. Any abnormalities of respiration should also be noted, including flaring of nostrils, extension of head and neck, grunting, abdominal press, and so forth. Normal resting respiratory rate is 10 to 30 per minute in adults and 20 to 40 in kids. Neonates should be inspected particularly for congenital defects. More commonly observed problems include brachygnathia, cleft palate, hydrocephalus, atresia ani, or rectovaginal fistula, and abnormalities of the genitalia associated with the intersex condition as discussed in Chapter 13. A list of congenital and inherited diseases is provided in Table 1.2. Not all of these, of course, will be evident at birth. Up-to-date information on inherited conditions of goats as well as

Figure 1.2. Typical waxy secretion found at the base of the tail of goats which is produced by the sebaceous glands in that area. This secretion should not be confused with diarrhea, vaginal discharge, or lochia. (Reproduced by permission of Dr. C.S.F. Williams.)

other species is available through the Online Mendelian Inheritance in Animals (OMIA) database at http:// omia.angis.org.au/. Goat stature is quite diverse. Many small breeds of goats such as the Pygmy or West African Dwarf goat are in fact achondroplastic dwarfs. They appear disproportionate with short legs and normal size torsos. This may draw visual attention to the degree of abdominal distension present, which though quite pronounced, is usually normal. Dwarfism because of pituitary hypoplasia is also seen in goats. These small goats are proportionate in appearance; the Sudan goat is an example (Ricordeau 1981). Examination of the Integument In goats the character of the skin and haircoat is a good indicator of general health. A rough, dry, unglossy coat; excessive dander or flakiness; and failure to shed

16 Goat Medicine Table 1.2. Congenital and inherited abnormalities in goats. Known inherited conditions

Known acquired conditions

Conditions of unclear status

Afibrinogenemia in Saanen goats Beta mannosidosis in Nubian goats Bipartite scrotum in Angora goats Brachygnathia superior or inferior Cryptorchidism in Angora goats Excessive facial hair in Angora goats Gynecomastia Hereditary goiter in Dutch goats Inherited abortion in South African Angora goats Intersexes associated with polled condition Myotonia congenita N-acetylglucosamine 6-sulphatase deficiency in Nubian goats (mucopolysaccharidosis IIID) Recessive atrichosis Robertsonian translocation Short tendons in Australian Angora goats Sperm granulomas Supernumerary teats Testicular hypoplasia

Anthrogryposis and hydranencephaly caused by Akabane virus Border disease Congenital copper deficiency Cyclopia due to Veratrum californicum Freemartins

Absence of hair Atresia ani Atresia coli Cleft palate Congenital goiter of Boer goats Double or fused teats Entropion Hydrops Patellar luxation Precocious milking Progressive paresis of Angora goats Rectovaginal fistula Skeletal malformations Spastic paresis Sticky kid syndrome of Golden Guernsey goats Umbilical hernia

out in the spring are all suggestive of poor nutritional status, parasitism, or other chronic diseases. The hair or fleece should be parted and the skin examined for lice, ticks, fleas (in the tropics), nodules, swellings, crusts, eczema, necrosis, neoplasia, photosensitization, and sunburn and focal or regional alopecia. The differential diagnoses for these findings are discussed in Chapter 2. Because many goats are used primarily for cashmere or mohair production, the veterinarian should know something about the nature of goat hair used in textiles. Detailed information on the subject is given in Chapter 2. Examination of the Head Many conditions can cause general asymmetry or focal swellings around the head and these abnormalities should be noted. The differential diagnoses for such swellings are discussed in Chapter 3. Membranes Inspection of the conjunctivae and mucous membranes of the mouth may reveal paleness due to anemia, icterus resulting from hemolysis or hepatic dysfunction, or hyperemia and congestion associated with acute febrile or toxemic states.

Oral Cavity Evidence of brachygnathism, cleft palate, mucosal lesions, dental abnormalities, or dysphagia such as drooling, salivation, dropping food from the mouth, or accumulating food in the buccal space should be noted. The differential diagnoses for these signs are given in Chapter 10. Necrotic odors of the breath may occur. They may reflect necrotic stomatitis, alveolar periostitis, pharyngitis, or even pneumonia. Thorough examination of the oral cavity requires good restraint, a speculum, a towel, and a penlight. All oral structures should be examined and the molar arcades digitally palpated for missing teeth from outside the mouth. If more direct examination of the teeth is required, extreme caution should be taken because the molars may have sharp, jagged edges and exert powerful grinding motion. Tranquilization is indicated, because fingers can be badly injured. Wearing gloves during oral examination is a wise precautionary measure, particularly if the goat shows neurologic signs. Eyes Facial hair covering the eyes is a heritable trait in Angora goats. Affected goats tend to do poorly on

1/Fundamentals of Goat Practice 17

range because their ability to selectively browse is impaired. The body condition of such individuals should be noted as well as their prevalence in the flock. Blindness is initially assessed by testing the menace response, but facial nerve paralysis can render a sighted animal unable to blink. Intact pupillary light responses in a blind goat suggest a cerebrocortical lesion. Lacrimation and hyperemia of the conjunctiva, cloudiness of the cornea, and hypopyon in the anterior chamber should be noted if present. The differential diagnoses for these various findings are given in Chapter 6. Nares Both nostrils should be evaluated for symmetry of air flow. If nasal discharge is observed, determine if it is unilateral or bilateral and note its character. Collapse of a nostril may result from facial nerve paralysis. Crusting of the nares occurs when the sick animal does not clean the nostrils or it may be a sign of specific disease problems. The differential diagnoses for nasal discharge and crusting of the nares are given in Chapter 9. Ears Ear mites, if suspected, can be identified by collecting debris from the ear canal on a cotton swab and smearing it on a slide for examination. Goats are often identified by tattoos inside the ear; tattoo numbers may have to be checked against health papers at shows and sales. It may be necessary to clean the inside of the ear with soap and water and use a powerful light source to backlight the tattoo to make it readable. Metal and plastic ear tags commonly tear out of goats’ ears and their use should be avoided, especially in pet and show animals. Ear tips may be lost on young goats due to prolonged exposure to freezing temperatures. Goats of the La Mancha breed lack a well-developed external ear. Only a vestigial pinna is present and is referred to as an elf (up to 5 cm, with some cartilage) or gopher (up to 2.5 cm, with little or no cartilage) ear. These animals are usually tattooed on the underside of the tail. Horns Goats may be horned or polled. Horn buds may be present at birth or become palpable within several days of birth. Generally, horned kids have two irregular whorls of hair over the location of the horn buds whereas hornless kids have a smooth poll with a single central symmetrical whorl of hair. It is important to establish and record which offspring are naturally polled because homozygous polled goats have a high incidence of infertility. The relationship of the polled trait and the intersex condition is discussed in detail in Chapter 13. Deformed horns, or scurs, are often seen

on older goats as a result of incomplete removal of germinal horn tissue at the time of disbudding. Techniques for, and problems with, disbudding and dehorning are discussed in Chapter 18. The glands partially responsible for the characteristic odor of buck goats in the breeding season are located in skin folds just caudomedial to the horn buds. Examination of the Neck Traumatic injuries to the pharynx from balling guns and drenching equipment occur in goats. The throat should be palpated for swelling, heat, and pain associated with cellulitis from traumatic injury. A number of normal and abnormal structures and swellings in the neck must be differentiated on physical examination, including goiters, thymus, branchial cleft cysts, wattles, and abscesses. Their differentiation is discussed in Chapter 3. Thorough examination of the neck should include palpation of the jugular furrows for evidence of phlebitis, palpation of the esophagus for evidence of obstruction, and auscultation of the trachea. Prominent distension of the jugular vein, though possibly suggestive of congestive heart failure, is most commonly due to overly tight collars or neck chains in goats. This should be brought to the owner’s attention if found. Examination of the Chest The extent and severity of respiratory disease is often difficult to assess in goats. To improve the chances of accurate diagnosis and prognosis, careful attention should be given to auscultation. When possible, the animal should be moved to quiet surroundings. The fleece in Angora goats should be parted to place the stethoscope in contact with the skin. The trachea and the lungs should be ausculted to identify the presence of referred sounds. Eliciting a cough by compression of the pharynx may clear the trachea or reveal the presence of bronchial exudate. Care should be taken to listen with a stethoscope placed well forward under the elbow and in front of the shoulder, otherwise cranial ventral pneumonias, which are common, may be overlooked. The intensity of identifiable sounds can be augmented by forced activity of the animal before auscultation or by placing a plastic bag or exam glove over the nares to increase the depth of respiration by rebreathing of carbon dioxide. Radiographic examination is indicated when questions about the severity of lung disease persist. Normally the heart can be heard about evenly on both the right and left sides of the chest at the fourth or fifth rib space. Mediastinal abscesses may displace the heart, resulting in a shift in intensity of cardiac sounds. Muffling of the heart sounds because of pericarditis is uncommon in goats. Murmurs are rarely heard and are discussed in Chapter 8.

18 Goat Medicine

Examination of the Abdomen The abdominal contour should be inspected to assess conditions such as bloat, advanced pregnancy in females, and ruptured bladder in wethers and intact males. Characteristic contours and their clinical significance are discussed in Chapter 10. Ballotment may help to detect abdominal fluid accumulations, pregnancy, or rumen impaction. Auscultation of the rumen in the left paralumbar fossa is essential. Normal rumen contractions occur at a rate of one to two per minute. Observation of cud chewing suggests normal rumen activity.

ary teats may be present. Their identification and removal are discussed in Chapter 14. The milk of lactating does should be observed on a black plate or strip cup to assess color, consistency, and the presence of clots or flakes. Bovine screening tests for subclinical mastitis such as the California Mastitis Test must be used cautiously in goats because normal goat milk tends to have higher cell counts. The somatic cell count issue and interpretation of test results are discussed in Chapter 14. Vulva

Examination of the Reproductive System

Swelling and hyperemia of the vulva may be signs of heat or impending parturition, but may also be seen in herpes vulvovaginitis in conjunction with vesicles or scabs. Any vulvar discharges should be noted. As females come out of heat, the vulvar discharge, initially serous and mucoid, may become white and tenacious. This is often misinterpreted as a purulent discharge by the inexperienced observer. Often, there is a sanguinous discharge after termination of a pseudopregnancy. Speculum examination of the vaginal canal and cervix should be carried out when there is doubt about the source and nature of the discharge. Occasionally, otherwise normal does may have ectopic mammary tissue present at the vulva which may swell during lactation. Does may show vaginal eversion or frank prolapse in advanced pregnancy or immediately post partum. After uncomplicated births, normal lochia may be discharged for a period of one to three weeks. It is reddish brown in color and odorless. Placentas are usually passed within four hours of parturition and are frequently eaten. It is important to carefully examine the external genitalia of young does, particularly when there is a complaint of infertility, because of the high incidence of intersexes among polled goats. Malformations of the genitalia range from the clinically subtle, such as a slightly enlarged clitoris, to the overt, such as male phenotypes in genetically female individuals. Accurate record keeping may help to identify homozygouspolled individuals.

Mammary Gland

Scrotum

Careful examination of the udder is always warranted. Visual inspection may reveal weakness of the suspensory apparatus, slack halves, abnormal swellings, and discolorations of the skin. Digital palpation of the gland will identify udder edema, active inflammation, fibrosis, scarring, or abscesses in the parenchyma or teats. In gangrenous mastitis the udder skin may be blue-black and cold and in time the gland may slough if the animal survives. Patency of the teats should be assessed in lactating animals. Supernumer-

The scrotum and its contents should be palpated. Normally there is bilateral symmetry of all structures. A bipartite or split scrotum is a common congenital condition that some breeders consider a fault. The differential diagnoses for abnormalities of the scrotum, testes, and spermatic cord structures are given in Chapter 13. Semen samples can be collected for evaluation by electroejaculation or by use of an artificial vagina. These procedures are described in Chapter 13. Gynecomastia occurs in male goats and it is not

Examination of the Limbs Locomotor problems are common in goats. Lameness and abnormalities of gait may result from neurological disease, conformational defects, muscular dysfunction, skeletal trauma, infectious and noninfectious arthritides, and diseases of the foot. Localization of the problem by careful physical examination is the first step in making an accurate diagnosis. Differential diagnoses of locomotor problems are discussed in detail in Chapter 4. Overgrown hooves must be pared with shears or a hoof knife to adequately assess the health of the foot. Hyperemia and swellings at or above the coronary band should be noted. They may represent either local infections or systemic disease. All joints should be carefully palpated. Distensions of the joint capsule, heat, pain, swelling or fibrosis of periarticular structures, limitations on the range of joint motion, and enlargement of bursae should all be noted. The degree of joint enlargement may not necessarily correlate with the severity of lameness. The vertebral column and the long bones of the legs should be palpated for evidence of fractures in acutely lame or recumbent animals. A major goal of physical examination in recumbent goats is to differentiate musculoskeletal, metabolic, toxemic, and neurologic causes of recumbency. The differential diagnoses for recumbency are discussed in Chapter 4.

1/Fundamentals of Goat Practice 19

extraordinary to detect distended teats anterior to the scrotum during physical examination, as discussed in Chapter 13. Penis and Prepuce Examining the penis of male goats, especially wethers, can be difficult and is not ordinarily attempted unless there is a history of urinary or breeding problems. Details on special examination and catheterization of the penis are given in Chapter 12. The preputial opening should be routinely examined, particularly in wethers, for the presence of ulcerative posthitis. The preputial orifice may become occluded in this condition. Crystals or drops of blood may be noted at the orifice in cases of obstructive urolithiasis. Examination of the Environment An examination of the environment where goats are raised should include a detailed review of all feeds used, the feeding facilities, water sources and water delivery systems; the yards, pastures, range, or buildings where the animals are kept; and any mechanical or manual equipment used as part of the routine farm procedures. Too often, farmers attempt to make do with equipment and buildings that are inadequate for an expanding operation. Because of prolificacy, goat herds tend to expand faster than owners anticipate. Inadequate feeder space for does, a smell of ammonia in the air due to poor ventilation and/or soaked bedding, and overcrowded kid pens are three examples of common faults found on environmental inspection. Besides visual inspection of equipment, farmers could be asked to demonstrate how common procedures are carried out to detect if they are using inappropriate techniques. Equipment used for treatment should be examined for its potential to cause injury. Poorly maintained syringes with either contaminated or overly long, large-gauge needles can result in injection abscesses or systemic infections. Drug and vaccine stocks should be examined to determine if they are appropriate, clean, unexpired, and maintained at proper temperatures. Storage facilities for these items should be properly secured. If the farmer blends his own feed or components, the techniques and constituents used should be examined, particularly when toxicities are suspected. Accidental inclusion of agricultural or other farm chemicals is not uncommon. Milking machines used for goats should also be examined to determine their efficiency and the milking procedures studied if it appears that mastitis is a significant problem. Finally, the facilities available and routinely used to dispose of any dead animals should be particularly noted to see that they are consistent with any legal requirements and do not serve as environmental contaminants or

as a source of infection for the remainder of the flock or herd. In recent years, in association with the expansion of international trade in livestock and livestock products and increasing concerns about bioterrorism, there has been a growing emphasis on food safety and biosecurity, with recognition that food safety encompasses all aspects of food production, from the farm to the table. As such, quality management assurance programs have grown in popularity as have procedures to ensure biosecurity to limit the introduction and spread of disease on and between farms. Environmental inspections should include an assessment of biosecurity and aspects of management and sanitation that can affect food quality. Special Considerations for Range and Pasture Operations The quality and quantity of pasture and the availability of supplementary or conserved feed should be assessed. This may require a specialized knowledge of pasture species, weeds, or other potentially toxic plants. A list of plants known to be poisonous to goats is provided in Chapter 19. If possible, animals should be observed while feeding. The source of water available both year-round and seasonally, its quality, and its quantity, should also be inspected. Feed and water samples should, if necessary, be collected for laboratory examinations. On range or pasture, goats may congregate in certain shaded or sheltered areas, particularly during periods of high or low temperatures or precipitation, and after shearing. Provision of adequate shelter should be documented. Heat stress can be reduced by ensuring the animals have adequate shade and water when the livestock weather safety index is in the danger or emergency zone. Cold stress is particularly likely in recently shorn animals, and temporary shelter and extra feed are necessary for these animals. If shelter areas are limited or overused, buildup of infectious agents can occur, leading to increases in enteric and other diseases, especially in kids. This is aggravated by poor drainage under feeders and water troughs. Fencing for these types of operations should also be inspected, particularly regarding its effectiveness in keeping goats in and keeping predators out. Special Considerations for Confinement Operations In semiconfinement operations adult animals and sometimes young stock are grazed on pasture during the warmer months but confined during the winter and early spring. As herds expand, there is a tendency for small pastures to be overused, with poor nutrition and increased parasitism as the result. Stocking rates should be noted and deworming history verified.

20 Goat Medicine

In confinement systems, the type of buildings used for housing should be evaluated for the following: available area (square feet or square meters) per adult breeding animal, type of flooring and bedding, degree of insulation, presence of supplemental heating if any, adequacy of natural or mechanical ventilation systems, source and availability of water, and the amount of trough or bunk space per goat. Requirements for goats are given in Chapter 9. The distribution of animals within buildings should be noted. Ideally, a separate kidding facility should exist and be hygienically maintained. Artificially reared kids should be in a separate facility from adult stock, and bucks should be housed separately from milking does. Methods and times of feeding for all groups within the herd should be noted. If other species of livestock are present, consideration should be given to them as possible sources of disease for goats. Unfortunately, many confinement goat operations have both rodent and associated feline populations. Cats are a recognized source of Toxoplasma gondii, a major cause of abortion in goats. Farmers should be encouraged to seek alternate means of rodent control. Special Consideration for Hobby Farms The principles and procedures of environmental examination already described also apply to the hobby farm. Special considerations that occur are usually the result of inexperience on the part of the hobbyist. Medications, insecticides, and grain supplies may be inadequately secured, allowing access of inquisitive goats with resultant overdoses, poisonings, and/or grain overload. In the barn, overcrowding with inadequate feeder space is often observed along with fecal contamination of feed and water supplies. In winter, lack of adequate ventilation in closed, overcrowded barns leads to outbreaks of pneumonia. Some owners consistently shut all windows and doors, believing that animals must stay warm in winter. These individuals need to be counseled on the beneficial effects of continuous air exchange on respiratory health. Pasture problems often involve disappearance of animals or predation due to inadequate fencing, bloat due to inadequate adaption to pasture, or parasitism due to placement of young stock on contaminated, overcrowded plots. The veterinarian should examine all elements of the ration being fed on the hobby farm to ensure that the hobbyist understands basic ruminant nutrition. Field Necropsies and Slaughterhouse Checks The economic value of most individual goats in commercial herds and flocks is such that most owners can be persuaded to have a necropsy undertaken of an ill or obviously moribund animal. This is an extremely useful adjunct to clinical examination, because nec-

ropsy can confirm the suspected diagnosis or suggest new avenues of investigation. All necropsies should be carried out following a systematic procedure with special regard to the likelihood of any zoonotic infections being transmitted and the safe and legal disposal of carcasses. Necropsy of all or a random sample of young animals born dead or dying in the first two to three weeks of life is an extremely valuable service that veterinarians can provide to their clients. Categorization of deaths into preparturient, parturient, and postparturient causes can be done with a minimum of laboratory diagnostic techniques and immediately direct the owner to possible ways of reducing these losses. Whenever possible, goats slaughtered for meat or culled from the herd or flock should be examined post mortem by a veterinarian as an inexpensive and worthwhile means of disease surveillance. Such inspections can provide information on the efficacy of parasite control measures; the presence of subclinical pneumonia; and the occurrence of injection site abscesses, visceral caseous lymphadenitis, and hydatid disease. Opportunities to perform routine slaughter checks on goats at an abattoir are uncommon in the United States because the goat meat industry is decentralized, though this may change as demand for goat meat continues to increase.

REFERENCES Askins, G.D. and Turner, E.E.: A behavioural study of Angora goats on west Texas range. J. Range Mgmnt., 25:82–87, 1972. Baguisi, A., et al.: Production of goats by somatic cell nuclear transfer. Nat. Biotech., 17:456–461, 1999. Batten, G.J.: A new meat goat breed. International Goat Association. Prcdngs, IV International Conference on Goats, Brasilia, March 8–13, 1987, Volume 2, pp. 1330–1331. Campbell, K.H.S., McWhir, J., Ritchie, W.A., and Wilmut, I. Sheep cloned by nuclear transfer from a cultured cell line. Nature, 380:64–66, 1996. Chavatte-Palmer, P., et al.: Clinical, hormonal, and hematologic characteristics of bovine calves cloned from nuclei from somatic cells. Biol. Reprod., 66:1596–1603, 2002. Coop, I.E., (ed): Sheep and Goat Production. Amsterdam, Elsevier Scientific Publ. Co., 1982. Dean, W., et al.: Conservation of methylation reprogramming in mammalian development: aberrant reprogramming in cloned embryos. Proc. Natl. Acad. Sci. USA, 98:13734–13738, 2001. Devendra, C. and Burns, M.: Goat Production in the Tropics. Slough, U.K., Commonwealth Agricultural Bureaux, 1983. Dubeuf, J.-P, Morand-Fehr, P., Rubino, R.: Situation, changes and future of goat industry around the world. Small Rum. Res., 51:165–173, 2004. Dunbar, R.: Scapegoat for a thousand deserts. New Scientist, 104:30–33, 1984.

1/Fundamentals of Goat Practice 21 Ebert, K.M., et al.: Transgenic production of a variant of human tissue-type plasminogen activator in goat milk: Generation of transgenic goats and analysis of expression. Bio/Tech, 9:835–838, 1991. Enright, B.P., et al.: Reproductive characteristics of cloned heifers derived from adult somatic cells. Biol. Reprod., 66:291–296, 2002. FAO: Livestock Units. In: ResourceSTAT Module of FAOSTAT, Food and Agricultural Organization of the United Nations, Rome, 2007. http://faostat.fao.org/site/405/default.aspx FAO: Livestock Primary and Processed. In: ProdSTAT Module of FAOSTAT, Food and Agricultural Organization of the United Nations, Rome, 2007a. http://faostat.fao. org/site/526/default.aspx Farin, P.W., Piedrahita, J.A., and Farin, C.E.: Errors in development of fetuses and placentas from in vitro-produced bovine embryos. Theriogenology, 65:178–191, 2006. Fletcher, C.J., et al.: Somatic cell nuclear transfer in the sheep induces placental defects that likely preceded fetal demise. Reprod., 133:243–255, 2007. Gall, C., (ed): Goat Production, London, Academic Press, 1981. Gavin, W.G.: Gene transfer into goat embryos. Transgenic Animals–Generation and Use. L.M. Houdebine, ed. Amsterdam, Harwood Academic Publishers, 1996. Gordon, J.W., et al.: Genetic transformation of mouse embryos by microinjection of purified DNA. Proc. Natl. Acad. Sci. USA, 77:7380–7384, 1980. Hafez, E.S.E. (ed): The Behaviour of Domestic Animals, 3rd Ed. Baltimore, The Williams and Wilkins Co., 1975. Hammer, R.E., et al.: Production of transgenic rabbits, sheep and pigs by microinjection. Nature, 315:680–683, 1985. Hill, J.R., et al.: Clinical and pathological features of cloned transgenic calves and fetuses (13 case studies). Theriogenology, 51:1451–1465, 1999. Honhold, N., Petit, H. and Halliwell, R.W.: Condition scoring scheme for Small East African goats in Zimbabwe. Trop. Anim. Health Prod., 21:121–127, 1989. Karreman, H.J.: Organic Livestock Production: Veterinary Challenges and Opportunities, 2006 Convention Notes, 143rd AVMA Annual Convention, Honolulu, July 15–19, 2006. Keefer, C.L., et al.: Generation of dwarf goat (Capra hircus) clones following nuclear transfer with transfected and

non-transfected fetal fibroblasts and in vitro matured oocytes. Biol. Reprod., 64:849–856, 2001. Kilgour, R. and Dalton, C.: Livestock Behaviour: A Practical Guide. Auckland, Methuen Publications Ltd. 1984. Kilgour, R. and Ross, D.J.: Feral goat behaviour—a management guide. N.Z.J. Agric., 141:15–20, 1980. Loi, P.L., et al.: Placental abnormalities associated with postnatal mortality in sheep somatic cell clones. Theriogenology, 65:1110–1121, 2006. Mahan, S.W.: The improved Boer goat. Small Rum. Res., 36:165–170, 2000. McGregor, B.A.: Heat stress in Angora wether goats. Aust. Vet. J., 62:349–350, 1985. Morand-Fehr, P., et al.: Strategy for goat farming in the 21st century. Small Rum. Res., 51:175–183, 2004. Nardone, A., Zervas, G., and Ronchi, B.: Sustainability of small ruminant organic systems of production. Livestock Prod. Sci., 90:27–39, 2004. Nieman, H. and Kues, W.: Application of transgenesis in livestock for agriculture and biomedicine. An. Reprd. Sci., 79:291–317, 2003. Peacock, C.: Improving Goat Production in the Tropics. Oxford, UK, Oxfam, 386 pp. 1996. Pu, Jiabi, Chengdu, Sichuan, China, personal communication, 1990. Reed, C.A. and Schaffer, W.M.: How to tell the sheep from the goats. Field Museum Nat. Hist. Bull., 43(3):2–7, 1972. Ricordeau, G.: Genetics: breeding plans. In: Goat Production, C. Gall, ed. London, Academic Press, 1981. Smith, P.W., Parks, O.W. and Schwartz, D.P.: Characterization of male goat odors: 6-trans nonenal. J. Dairy Sci., 67:794–801, 1984. Tayfur Tecirlioglu, R., et al.: Semen and reproductive profiles of genetically identical cloned bulls. Theriogenology, 65:1783–1799, 2006. Walsh, M.K., et al.: Comparison of milk produced by cows cloned by nuclear transfer with milk from non-cloned cows. Cloning and Stem Cells, 5:213–219, 2003. Ward, M.L.: Cleaning up with goats. Beef Magazine. 42(12):46–47, August, 2006. Wells, D.N.: Animal cloning: problems and prospects. Rev. sci. tech., Off. Int. Epiz., 24 (1):251–264, 2005. Wilmut, I., et al.: Viable offspring derived from fetal and adult mammalian cells. Nature, 385:810–813, 1997.

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2 Skin Normal Anatomy and Physiology of the Skin and Hair 23 Skin 23 Specialized Skin Structures 23 Hair and Shedding 24 Fiber Production 24 Mohair 24 Cashmere 25 Cashgora 26 Pygora 26 Production of Skins 26 Diagnosis of Skin Disease 26 History 26 Clinical Signs of Skin Disease 27 Body Localization as an Aid to Diagnosis 28 Clinical Laboratory Examination 29 Etiologic Diagnoses 30 Viral Diseases 30 Contagious Ecthyma 30 Capripox 32 Miscellaneous Virus Infections 33 Bacterial Diseases 34 Staphylococcal Dermatitis 34 Dermatophilosis 35 Corynebacterium pseudotuberculosis 36 Actinobacillosis, Actinomycosis, and Protothecosis 37 Fungal Diseases 37 Ringworm 37 Yeast Infections 37 Miscellaneous Fungal Infections 38 Parasitic Diseases 38 Lice 38 Fleas 39 Keds 39 Biting Flies, Gnats, and Mosquitoes 39 Cutaneous Myiasis 40 Warbles 40 Ticks 41

NORMAL ANATOMY AND PHYSIOLOGY OF THE SKIN AND HAIR The structure and function of the skin have been reviewed elsewhere (Scott 1988) and will not be discussed in detail here. Skin The epidermis can be divided histologically into four layers: stratum corneum, stratum granulosum, stratum spinosum, and stratum basale (Sar and Calhoun 1956). Goat skin is thickest on the forehead Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Sarcoptic Mange 42 Chorioptic Mange 43 Psoroptic Mange 43 Raillietia 44 Demodectic Mange (Demodicosis) 44 Free-living Mites 45 Rhabditic Dermatitis and Strongyloidiasis 45 Parelaphostrongylosis and Elaphostrongylosis 46 Filarid Dermatitis 46 Besnoitiosis 46 Nutritional Diseases 47 Zinc Deficiency and Zinc Responsive Dermatosis 47 Iodine Deficiency 48 Vitamin A Deficiency 48 Vitamin E and Selenium Responsive Dermatosis 48 Selenium Toxicity 49 Sulfur Deficiency 49 Environmental Insults 49 Sunburn 49 Photosensitization 49 Kaalsiekte 50 Frostbite 50 Ergotism 50 Urine Scald 50 Other Contact Dermatitis Conditions 50 Neoplasia 51 Papilloma 51 Udder Warts 51 Carcinomas 51 Melanomas 51 Inherited or Congenital Conditions 52 Miscellaneous Conditions 52 Pemphigus 52 Alopecic Exfoliative Dermatitis, Psoriasiform Dermatitis 52 Lichenoid Dermatitis 53 Allergy or Hypersensitivity 53 References 53

and dorsal aspect of the body. As in other species, the major histocompatibility system is involved in allograft rejection if skin grafting is attempted (van Dam et al. 1978). Specialized Skin Structures Wattles are specialized skin appendages sometimes found in the cervical region of goats. They contain a central cartilaginous core, smooth muscle, connective tissue, nerves, and blood vessels (Sar and Calhoun 1956). Wattles have no known function. Subcutaneous 23

24 Goat Medicine

cysts associated with the base of the wattle are discussed in Chapter 3. The presence of wattles is determined by an autosomal dominant gene with complete penetrance but variable expression regarding location (neck, ear, face), size, and number (Lush 1926; Ricordeau 1981). In a study of Saanen goats in France, does with wattles were approximately 13% more prolific than does without wattles (Ricordeau 1967). The skin caudomedial to the horns of buck goats contains branched sebaceous glands that produce lipids and chemicals that contribute to the buck odor (Van Lancker et al. 2005). The glands are also present but much smaller in female and castrated male goats (Bal and Ghoshal 1976). These glands and descenting procedures that destroy them are discussed in Chapter 18. Hair and Shedding Hair growth in goats resembles that in other land mammals (Shelton 1981; Scott 1988). Hair follicles are initiated prenatally by invagination of the epidermis into the dermis. Sweat and sebaceous glands and the arrector pili muscle develop in association with the follicle. The histologic anatomy of these structures has been reviewed by Scott (1988). The hair is produced by rapidly dividing cells in the bulb at the base of the follicle. During the active phase of the growth cycle (anagen), growth from the bulb is continuous. Anagen is followed by the resting phase (telogen) and then by molting. When growth resumes, the new fiber produced by the follicle helps to push out the old fiber. In goats not specifically selected for fiber production, fibers form brush ends and growth stops at about the time of the autumn equinox, and the follicles remain dormant until late spring (Ryder 1978). Hair follicles in goats are grouped in bundles or clusters. Within each bundle are primary follicles (often a central and two laterals) and a variable number of secondary follicles. The primary follicles produce long, coarse guard hairs, while secondary follicles produce undercoat or down. In the Angora, secondary follicles have been modified to produce mohair. Goats adapted to tropical regions have little undercoat, while secondary fibers contribute to cold resistance in goats in cold climates. The inheritance of coat color involves numerous genes. One possible interpretation of color in American goats has been proposed by Mitchell (1989). Several other papers have attempted to summarize various aspects of color inheritance in goats (Ricordeau 1981; Adalsteinsson et al. 1994).

FIBER PRODUCTION Certain breeds of goats are kept specifically for fiber production. Anything that adversely affects the quality and quantity of fiber harvested, including skin dis-

Figure 2.1. Angora goats, the source of mohair. (Courtesy Dr. M.C. Smith.)

eases, can have severe economic consequences. Branding paint also damages the fleece, and thus range animals should be paint branded only on the ears or horns. Mohair Mohair is the fleece of the Angora goat (Figure 2.1). The Angora evolved in Asia Minor many centuries ago, possibly a descendant of the wild goat of Persia. Mohair probably developed by elongation of the woolly undercoat of the primitive goat. Although the sultans of Turkey attempted to prevent exportation, populations of Angora goats reached South Africa and the United States in the mid-1880s. Currently, important production centers for mohair include South Africa, Texas, Turkey, Argentina, New Zealand, and Australia (Dubeuf et al. 2004). Factors Affecting Mohair Quality Mohair mainly consists of nonmedullated fibers that lack crimp. They arise mostly from secondary follicles and grow continuously, albeit at a lower rate in winter. These fibers are strong, elastic, and composed of keratin. Flat scales that hardly overlap give the fibers smoothness and luster (Margolena 1974). Different countries have different standards for fiber diameter, but the range is typically 24 to 46 microns. The fleece is typically harvested in two clips per year. KEMP. At birth, goat fleece contains approximately 44% kemp, or medullated fibers from primary follicles, but this proportion drops to 7% by three months of age due to shedding of the kemp (Dreyer and Marincowitz 1967). Later in life, some primary follicles may produce fibers with discontinuous or no medullation. Kemp and colored fibers are generally undesirable fleece contaminants due to uneven dyeing. It has been proposed that shearing shortly before the spring and autumn equi-

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noxes decreases the proportion of medullated fibers in the clip, because natural shedding of these fibers will have recently occurred (Litherland et al. 2000). PERINATAL NUTRITION. In the developing fetus, a central and two (or more) lateral primary follicles are in place by ninety days of gestation (Wentzel and Vosloos 1974). The development of secondary hair follicles occurs later and is affected by nutrition during the fourth month of gestation through the first month after birth. Poor nutrition during these critical times probably will compromise the Angora goat’s ability to produce mohair later in life (Eppleston and Moore 1990). AGE AND NUTRITION. Hair follicle density in the skin determines fiber density in the fleece and is under both genetic and nutritional control. Fiber diameter increases with age and bodyweight. Kids produce mohair with a fiber diameter of 28 microns or less at the first shearing, whereas the diameter of the fibers from adult goats varies from 36 to 46 microns. The mohair mass produced peaks at three to four years of age, but because the finer fibers are more valuable, the economic value of the fleece peaks somewhat sooner (van der Westhuysen et al. 1988). Under nutrition results in reduced body growth and production of mohair as well as a reduction in fiber diameter (Russel 1992). Thus, finer, lighter fleece is produced during periods of drought or overstocking. A slightly coarser fleece may result from overfeeding, although published documentation of this is scarce. In one study in which Angoras were fed individually to maintain different bodyweights, fiber diameter increased 0.4 microns for each kilogram increase in bodyweight (McGregor 1986). Nutrition of Angora goats is discussed more in Chapter 19. STRESS MEDULLATION. A reversible change from normal to medullated fibers occurs in a stress syndrome that seems to be comparable to wool break in sheep. Reported causes of stress-induced medullation include lactation for twins, transport, and hard work by bucks. The time period when the stress occurred can be demonstrated by immersing a full-length staple of fleece in kerosene in a black container. Kemp fibers and bands of medullation in mohair will show as white streaks due to air-filled cores. Normal mohair is almost invisible in kerosene (Ensor 1987). Other possible causes of medullation have been reviewed (Lupton et al. 1991). Dietary protein and energy levels do not seem to be important in individually housed animals, but heredity may contribute. Selection should be based on objective evaluation of whole fleeces, not just mid-side samples, of Angora goats older than one year of age.

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and temperature changes. Angoras have minimal body fat and a small body size, with relatively greater surface area, as compared to sheep. Mortality can be very high in freshly shorn goats, especially if they have not had time to return to full feed before inclement weather arrives. Methods of limiting freeze loss include sheltering the animals for four to six weeks after shearing, shearing with a comb that leaves a longer stubble, and leaving a narrow strip of unshorn hair (“cape”) along the backbone (Shelton 1981; Bretzlaff 1990). Feeding of alkali-ionophore-treated grains (to avoid rumen acidosis, see Chapter 19) is helpful when shorn animals are exposed to severe weather. Individual recumbent animals may respond to intravenous or intraperitoneal glucose (van der Westhuysen et al. 1988). Cashmere Cashmere is a fine, soft fiber used to produce fashion-wear. It comes from the downy undercoat of certain goats (Figure 2.2). Originally, cashmere was combed from Pashmina goats in Central Asia (Mason 1984). Goat down (unmedullated, from secondary follicles) with a mean fiber diameter of 19 microns or less can be produced by many breeds. By comparison, the mean diameter of the guard hair outer coat is typically 60 to 90 microns. Latitude, and therefore photoperiod, appear to be more important than altitude as a factor influencing down production. Evidence of this is that most Australian cashmere production occurs near sea level (Couchman 1987). In spring-born kids, maximum secondary follicle development (as determined by skin biopsy or fiber measurements) is achieved by 20 weeks of age, permitting selection at that time (Henderson and Sabine 1991).

Freeze Loss Whenever Angoras are shorn, even during summer months, they are vulnerable to exposure to wind, rain,

Figure 2.2. Cashmere goats from Mongolia. (Courtesy Dr. M.C. Smith.)

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Cashmere goats have a three-phase annual cycle of fiber growth that is influenced by photoperiod, probably via melatonin (Klören and Norton 1995), and nutrition. The period of fiber growth typically coincides with summer in wethers and maiden does but is often delayed until autumn and early winter in lactating does (McDonald 1985). Next, fiber regression occurs and the root bulb of the fiber forms an enlarged brush end, which holds the fiber in the follicle. Finally, there is a follicle resting phase when no down is grown and improved nutrition has no direct effect on cashmere production. The fiber is shed (or the entire fleece may be cast simultaneously) when the fibers are lost from the secondary follicles. The fleece may be harvested by shearing just before it would be shed naturally, usually at the end of the winter. Freeze losses of shorn goats may occur. It may be several months before normal seasonal growth resumes (Betteridge et al. 1988). Chemical defleecing with mimosine has been investigated as a means of leaving the protective guard hairs on the goat (Luo et al. 2000). Raw, or greasy, cashmere contains both guard hairs and down. Dehairing machinery removes the long guard hairs that remain after hand removal of most of the coarse hairs. Major suppliers of the raw fiber are China, Mongolia, Afghanistan, and Iran. The maximum guard hair content after dehairing is 0.5% for knitting and 3% for the weaving trade. Imported cashmere is sometimes contaminated with anthrax (Bacillus anthracis) spores (Hunter et al. 1989). As with mohair, the finest cashmere fibers are produced under conditions of nutritional stress. In an Australian study, however, feeding enough energy to maintain or slightly increase body condition during summer and autumn maximized cashmere production. Fiber diameter of the total fleece averaged 1 micron larger for goats fed energy at 1.25 maintenance (M) compared with 0.8 M (McGregor 1988).

PRODUCTION OF SKINS The annual worldwide production of goat skins was estimated at 200 million in 1983. Of these, 95% were produced in developing countries (Robinet 1984). The estimate for 1995 was 295 million pieces, with India, China, and Pakistan remaining important producers of goat leather products (Naidu 2000). The quality of the skins produced is influenced by breed, nutritional status of the goat, disease conditions affecting the skin, and traumatic injuries (e.g., from injections, thorns, and dog bites). Angora skins are considered to be unsuitable for leather production because of insufficient connective tissue (van der Westhuysen et al. 1988). Local drought conditions result in particularly weak skins. Mange, grubs, tick infestations, capripox and contagious ecthyma infections, and dermatophilosis decrease the value of goat skins. When the goat has been slaughtered, additional losses occur during flaying, drying, and storage. Humid weather predisposes to rotting while extremely arid conditions make cracking of the skins more likely. Goat skins are used in local villages for water containers, tents, mats, and leather. Others are exported as cured skins, simple tanned skins, drum heads, or leather. Uses include footwear, garments, bookbinding, and luggage. The demand is expected to remain steady. Production could be most easily increased by limiting wastage (Holst 1987).

DIAGNOSIS OF SKIN DISEASE

Cashgora is a coarse cashmere with more luster, mostly harvested from the progeny produced by crossing Angoras with feral goats in Australia and New Zealand. The current fiber diameter is 20 to 23 microns. Some breeders are attempting to stabilize the fleece type.

The ideal approach to the diagnosis of skin disease is a logical progression from history, to an overall clinical examination of the goat, to a detailed examination of the skin, and finally to confirmatory testing or diagnosis by response to therapy. The experienced clinician often performs these steps subconsciously and in an abbreviated fashion. For instance, if contagious ecthyma has been diagnosed on the farm in past years and now three otherwise sleek and healthy kids have proliferative scabs restricted to the lips and muzzle, the prior probability that these kids also have contagious ecthyma is so high that no additional testing is justified. On the other hand, when the skin disease is unusual, chronic, or refractory to initial therapy, the entire sequence should be followed for best results.

Pygora

History

Pygoras are a newly developed breed resulting from the crossing of purebred pygmy goats and purebred Angoras. Two such “first generation crossbreds” are mated to produce the actual pygora. Currently registration requirements include fleece evaluation. The soft undercoat resembles cashmere, comes in a variety of colors, and is often plucked or combed for sale to handspinners in the United States (Hicks 1988).

Historical information to gather includes details on feeding and management, health history of the affected animals, date when signs were first noticed, and any apparent spread to others in the herd. It is also important to determine if there has been any contact, however brief, with goats or other ruminants from other farms, and what treatments have already been applied with what results (Jackson 1986).

Cashgora

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Clinical Signs of Skin Disease A reasonably short differential diagnosis list can usually be generated if close attention is paid to primary lesions (those directly reflecting the underlying disease). Primary lesions include papules, vesicles, pustules, and nodules. Secondary lesions such as scales, crusts, and alopecia are often the result of selftrauma or superimposed bacterial infections. Secondary lesions are less helpful for making a diagnosis, but may suggest the need for symptomatic therapy. Subcutaneous lesions are discussed in Chapter 3. Papules A papule (pimple) is a circumscribed solid mass less than 1 cm in diameter that is usually elevated and erythematous. Follicular papules suggest bacterial, fungal, or parasitic infection whereas papules without a hair follicle at the center are typical of allergy and ectoparasites. A large flat-topped lesion, usually arising from confluent papules, is termed a plaque. Vesicles and Pustules A vesicle is a papule-shaped fluctuant elevation containing serum. Vesicles are transient and suggest autoimmune, irritant, or viral etiologies. A pustule is a pus-filled vesicle and indicates infection if follicular in orientation but may be autoimmune (pemphigus) if non-follicular. Demodicosis is a common pustular disease in goats. Pox lesions (contagious ecthyma, capripox) follow a typical progression from papule, to vesicle, to pustule, to a crust or proliferative lesion. Hyperkeratosis Hyperkeratosis is an increased thickness of the stratum corneum. The term is often used in place of the more precise term orthokeratotic (anuclear) hyperkeratosis. Parakeratotic hyperkeratosis (often called parakeratosis) differs in that nuclei remain in the keratinized layer of the skin. Both of these conditions are common and nondiagnostic histologic findings in chronic skin diseases of many sorts. Diffuse parakeratosis suggests ectoparasitisms, seborrhea, zinc responsive disease, dermatophytosis, and dermatophilosis (Scott 1988). During physical examination, hyperkeratosis is used to refer to accumulations of adherent keratinized material.

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tion has occurred and thus have multiple causes. Close examination (crust biopsy), however, may reveal diagnostic clues such as dermatophyte hyphae, Dermatophilus, or many acantholytic keratinocytes (pemphigus complex). Crusts are said to be pallisading when layers of keratin and exudate alternate, as is common in dermatophilosis and dermatophytosis. Bacterial colonies are to be expected in all crusts, whatever the cause, and have no diagnostic significance. Alopecia Spontaneous hair loss occasionally occurs in Angoras and more often in crossbreds, mainly at the end of winter. Shearing at an inappropriate time is thought to increase the risk of hair loss. Nutritional deficiencies or imbalances (such as high calcium with low zinc) have also been incriminated (van der Westhuysen et al. 1988). There are anecdotal reports that hair loss and scaling along the dorsal spine of adult goats resolve when an organic zinc supplement is added to the concentrate portion of the ration. Periorbital alopecia (with mild scaling) is often prominent in vitamin E or selenium responsive dermatosis and alopecic exfoliative dermatitis. There are also anecdotal reports of almost complete hair loss (early shedding) in dairy does that have been subjected to photoperiod manipulation for out-of-season breeding. Partial alopecia (hypotrichosis) is a nonspecific secondary lesion. Alopecia can be induced by self excoriation when pruritus is present or can be the result of grooming by pen mates (Figure 2.3). Pruritus Pruritus, or the semblance of itching, frequently leads to excoriations and other secondary lesions. If pruritus is severe, special consideration is given to the

Scales and Crusts Scales (squames, flakes) are loose fragments of stratum corneum. Admixture with sebaceous and apocrine secretion makes the scales yellowish, greasy, and adherent. Crusts are solid adherent combinations of materials such as serum, blood, pus, keratin, microorganisms, and medications. They indicate that exuda-

Figure 2.3. Alopecia on the side of a wether caused by grooming by its pen mate, a white-tail deer. (Courtesy Dr. M.C. Smith.)

28 Goat Medicine

possibility of sarcoptic or chorioptic mange. Other conditions that may be pruritic include lice, fleas, hypersensitivity to other insects such as Culicoides, zinc deficiency, pemphigus, and photosensitization. Occasionally, bacterial or fungal dermatitis is mildly pruritic. If vertically oriented linear excoriations develop, migration of Parelaphostrongylus tenuis through the spinal cord or dorsal nerve roots should be considered. Acute pruritus in a goat that dies very soon after clinical signs are noted is suggestive of pseudorabies (Baker et al. 1982). Extreme pruritus but with a longer clinical course has been reported in a single goat with confirmed rabies (Tarlatzis 1954). Pruritus was reported as a clinical sign in 11 of 20 goats in Great Britain with scrapie (Wooldridge and Wood 1991) and in more than 80% of 500 goats developing scrapie in Italy after infection via a contaminated contagious agalactia vaccine (Capucchio et al. 2001).

present only on the ventrum may result from contact dermatitis or parasite invasion. Lesions present only on nonpigmented skin may be caused by photosensitization or sunburn.

Erythema

• • • • • • • •

Erythema, or reddening of the skin, occurs in many acute disease conditions and is thus not diagnostic. It is an early sign in photosensitization. When a chronic disease condition also has crusting and alopecia, response to therapy may be difficult to judge. Subsidence of a previously prominent erythema suggests improvement, even before hair regrowth is noted. Pigmentary Changes Few skin diseases in goats are associated with pigmentary changes. Decoloration of hair might occur with copper deficiency because a copper-containing enzyme is necessary for melanin production. Affected Toggenburg goats and repigmentation with copper supplementation have been reported (Lazarro 2007). Light-skinned Saanen goats normally develop large irregular areas of black pigmentation when exposed to sunlight. The color fades with confinement away from the sun. Absence of Skin

Lips, Face, and Neck • • • • • • • • • • •

Contagious ecthyma Capripox Peste des petits ruminants Bluetongue Staphylococcal folliculitis Dermatophilosis Dermatophytosis Sarcoptic mange Zinc deficiency Pemphigus foliaceus Protothecosis

Ears Dermatophilosis Dermatophytosis Sarcoptic mange Ear mites Photodermatitis Squamous cell carcinoma Frostbite Pemphigus foliaceus

Feet • • • • • • • • • • • •

Contagious ecthyma Foot and mouth disease Staphylococcal folliculitis Dichelobacter infection (foot rot) Dermatophilosis Sarcoptic mange Chorioptic mange Pelodera dermatitis Besnoitia dermatitis Zinc deficiency Contact dermatitis Pemphigus foliaceus

Cutaneous asthenia, a congenital skin defect seen in sheep where the skin is abnormally fragile and easily torn, has apparently not been reported in goats. There is an anecdotal report of epitheliogenesis imperfecta, where a portion of the epidermis is absent, in a pygmy goat (Konnersman 2005b).

Udder

Body Localization as an Aid to Diagnosis

Perineum

The entire body surface should be examined. The distribution of skin lesions over the body helps to arrive at a diagnosis. Listed here are some diseases found initially or most severely on the extremities of goats. These diseases are characteristically but not invariably found in the specified locations. Lesions

• • • • • •

• • • • •

Contagious ecthyma Staphylococcal folliculitis Zinc deficiency Hyperpigmentation from exposure to sun Neoplasia

Contagious ecthyma Caprine herpesvirus Staphylococcal dermatitis Ticks Neoplasia Ectopic mammary gland

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Clinical Laboratory Examination Simple observation allows identification of most of the clinical signs of skin disease, and thus many conditions can be diagnosed with reasonable certainty with just the findings of a physical examination. However, the repertoire of injured skin is limited, and the same sign (such as a pustule or crust) may occur in a variety of conditions of different etiologies. Skin Scrapings When searching for surface-dwelling ectoparasites such as lice and nits or chorioptic mange mites, a flea comb can be used to harvest scales and crusts or hair from extensive portions of the body. The collected sample is then placed in a petri dish or ziplock plastic bag for transport to good light or even a dissecting scope. After initial visual examination, the sample next undergoes a fecal flotation procedure. Mites and eggs come to the surface with centrifugation and can thus be concentrated and separated from the debris that would otherwise obscure their presence. Repeated, deep scrapings using a scalpel blade dipped in mineral oil are usually necessary to identify sarcoptic mange mites or their eggs. A few drops of 20% potassium hydroxide solution are added to the sample, a coverslip is applied, and clearing of debris allowed to proceed for 15 to 30 minutes before microscopic examination. Larger samples may be processed by boiling 10 minutes in 10% potassium hydroxide solution, centrifuging, and performing a sugar flotation on the sediment. Direct microscopic examination of hair and keratin is useful for demonstrating the presence of dermatophytes. Ectothrix infections of hair shafts often can be seen if the specimen is placed in mineral oil. Clearing in potassium hydroxide solution, as for mite identification, is another option. Bacterial Examination Skin lesions in goats are almost invariably heavily contaminated by bacteria, including Staphylococcus aureus. A culture is most meaningful, then, if material is aspirated from an intact pustule, nodule, or abscess. A punch biopsy obtained after careful disinfection of the skin surface is suitable for culture if intact puscontaining structures are absent. Routine inoculation onto a blood agar plate (aerobic) and into thioglycolate broth (anaerobic) is recommended. More immediate guidance can be derived by making a direct smear of an aspirate or deep aspect of a biopsy specimen and staining with new methylene blue, Gram’s, or Diff Quik® (Harleco, Gibbstown, NJ) stain. Such a preparation should reveal bacteria within neutrophils and macrophages if they are pathogenic, rather than contaminant bacteria that will be extracellular and clumped

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in colonies. Gram-positive branching filaments are typical of dermatophilosis. Fungal Culture When ringworm is suspected, hairs should be plucked from the periphery of an active lesion after swabbing the area gently with 70% alcohol solution to discourage the growth of bacteria and saprophytic fungal contaminants. Sabouraud’s dextrose agar (Sab Duet®, Bacti Labs, Mountain View, CA) is routinely used. Most strains of Trichophyton verrucosum require thiamine for growth; this can be supplied by adding 1 to 2 ml of injectable B-complex vitamins to the culture plate, but products containing alcohol should be avoided. The cultures are incubated at 86°F (30°C) with a pan of water in the incubator to maintain adequate humidity. Cultures should be checked every day for thirty days. Standard texts should be consulted for identification of fungal isolates (Scott 1988). Biopsy for Histology A biopsy should be performed if a skin disease appears to be unusual or severe and especially if there has been no response after three weeks of initial therapy. Several areas are selected as having typical or primary lesions and marked by drawing a circle with a felt-tipped pen. The skin is prepared by clipping hair and injecting lidocaine subcutaneously at each chosen location. The skin must never be scrubbed. In very small kids, dilution of the lidocaine to 1% or 0.5% may be advisable. A 6-mm punch (Baker/Cummins, Miami, FL) is used to cut out a full thickness skin sample, which should be blotted flat, dermis side down, onto a small piece of a tongue depressor. The skin specimen quickly adheres to the wood; it can then be dropped upside down into a vial of 10% buffered formalin, where the wood will keep it suspended in the preservative. The skin defect is closed with absorbable suture. Consideration should be given to the tetanus vaccination status of the animal and tetanus antitoxin or toxoid given if indicated. The testing laboratory should be consulted if electron microscopic examination is required (as for pox). Glutaraldehyde is usually the preferred fixative. Immunofluorescence Testing An autoimmune skin disorder (pemphigus foliaceus) may be suspected from clinical signs or after routine histologic examination of a skin biopsy specimen. If confirmation with direct immunofluorescence testing is desired, a new skin sample (with intact vesicles and pustules) should be procured and fixed with Michel’s fixative, which is best obtained from the laboratory that will perform the testing. Glucocorticoids should not be administered for at least three weeks

30 Goat Medicine

before testing to avoid false negative results (Scott 1988). Diffuse intercellular deposition of immunoglobulin is found in caprine pemphigus.

ETIOLOGIC DIAGNOSES Readers who desire a more exhaustive reference list for any of the conditions described below should consult D.W. Scott’s Large Animal Dermatology textbook (1988). Several review papers also discuss dermatologic diseases of goats (Smith 1981, 1983; Mullowney and Baldwin 1984; Scott et al. 1984a, 1984b; Manning et al. 1985; Jackson 1986 ) and many are illustrated in a recent text (Scott 2007).

VIRAL DISEASES Contagious ecthyma and capripox viruses cause prominent skin lesions in goats. Virus infections involving other body systems also may have cutaneous manifestations. Warts (cutaneous papillomas) in goats have not been proven to be of viral origin and are discussed under neoplastic conditions. Contagious Ecthyma Contagious ecthyma is a contagious, zoonotic disease of goats and sheep (and camelids) that has several alternative names, including orf, soremouth, scabby mouth, and contagious pustular dermatitis. It has worldwide distribution. Etiology and Epidemiology The cause is an epitheliotropic parapoxvirus that enters the goat through skin abrasions (Mayr and Büttner 1990). The virus replicates in proliferating keratinocytes in the damaged epidermis (McKeever et al. 1988) and then causes a primary viremia to lymph nodes, bone marrow, and liver. In some cases, the virus then becomes generalized, with a second viremic phase, and spreads to the head, extremities, udder, genitals, lungs, and liver (Mayr and Büttner 1990). The morbidity in young kids often approaches 100%, while mortality from starvation and secondary infections may be as high as 20% (Van Tonder 1975) but is usually much lower. Scabs that fall to the ground during resolution of lesions have long been incriminated as the source of infection to other animals months or even years later (McKeever and Reid 1986), and this is indeed possible if the environment remains dry. More recently, persistently infected carrier sheep, some of which are asymptomatic, have been demonstrated to be an important source of contagion (Lewis 1996). Presumably carrier goats also occur, and infection can be activated by stress (Mayr and Büttner 1990). Clinical Signs The incubation period is three to eight days (Mayr and Büttner 1990). Papules progress rapidly to vesicles,

pustules, and scabs. Crusty, proliferative lesions typically form on the lips but can also affect the face, ears, coronary band, scrotum, teats, or vulva. In one outbreak, where exposure presumably occurred in contaminated pens at a show, lesions occurred on the neck, chest, and flanks of seven goats rather than on the lips or teats (Coates and Hoff 1990). In another case report, lesions were most common on haired skin of adult goats and the first crusty scabs noticed were on the caudal aspect of the hind legs (Moriello and Cooley 2001). The scabs frequently harbor secondary bacteria (such as staphylococci) or even screwworm maggots (Boughton and Hardy 1934). Sometimes large masses of granulation tissue develop under the scabs. Lesions regress in three or four weeks. Most adult goats with lesions on the lips (Figure 2.4) continue to eat and milk well. Occasional goats, especially young kids exposed to other diseases or management deficiencies, will develop generalized lesions or severe secondary bacterial infections. Lesions on the teats of milking animals may compromise the health of the sphincter and predispose to bacterial mastitis. Associated pain may cause the doe to reject nursing efforts by its kid. Severe generalized and persistent proliferative lesions have been seen in Boer goats and their crosses in the United States (Figure 2.5). Draining lymph nodes are markedly enlarged in these animals, and thymic atrophy is often present. Preliminary research has not proven whether this variation represents a viral strain difference or a difference in immune

Figure 2.4. Healing crusts from contagious ecthyma on the muzzle of a mature doe. One large scab has fallen off, leaving healthy skin beneath. (Courtesy Dr. M.C. Smith.)

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Figure 2.5. Severe contagious ecthyma lesions on the gums of a Boer kid. (Courtesy Dr. M.C. Smith.)

response of the affected Boer goats (de la ConchaBermejillo et al. 2003; Guo et al. 2003). Close examination of many sheep and goats with a more typical presentation of contagious ecthyma often reveals a mild lymphadenopathy. Diagnosis Diagnosis is usually based on clinical signs alone, although electron microscopy or immunologic techniques to demonstrate antigen in scabs or serology could be used for confirmation or to rule out capripox infection (Robinson and Balassu 1981). In lambs experiencing contagious ecthyma, serum antibodies often do not appear until after reexposure (Mayr and Büttner 1990). Similarly, rural physicians usually make the diagnosis in their human patients on clinical signs alone, but urban dermatologists lacking experience with the disease may insist on biopsy for histologic or electron microscopic examination (Gill et al. 1990; Green et al. 2006). Skin biopsies of ruminants reveal ballooning degeneration of keratinocytes and eosinophilic cytoplasmic inclusions (Robinson and Balassu 1981; Scott 2007), although the inclusions are not always detectable (Housawi et al. 1993). The crusts consist of multiple layers of necrotic cellular debris and neutrophils. Histopathology helps to distinguish contagious ecthyma from the convalescent stages of peste des petits ruminants. Therapy The possible beneficial effects of treatment must be weighed against the danger of zoonotic infection (Figure 2.6). Any person handling an affected goat should wear gloves. Numerous products have been used topically, with anecdotal reports of faster healing.

31

Figure 2.6. Orf (contagious ecthyma) lesion on the author’s wrist. (Courtesy Dr. M.C. Smith.)

However, these products have been used with minimal consideration of meat and milk residues. These include kerosene mixed with lard, penetrating oil spray (WD40®), and bismuth subsalicylate (Pepto-Bismol®). Systemic antibiotics are indicated if secondary bacterial infections are severe. An udder salve is indicated to keep scabs on the teats pliable. If painful, proliferative lesions within a kid’s mouth cause feeding to decrease, the kid could be anesthetized and subjected to debridement (electrocautery after spray cryotherapy). This approach has been used in lambs with good results (Meynink et al. 1987). Vaccination Commercially available vaccines often are unattenuated live virus preparations (basically ground-up scabs) or are tissue culture strains, although the level of protection afforded by the latter appears to vary with the strain (Pye 1990). An autogenous vaccine can be made by crushing, in saline, a few grams of scabs between two spoons or with a mortar and pestle. The suspension is filtered through cheesecloth and a few drops of antibiotic solution such as penicillin/streptomycin are added to control bacteria (Bath et al. 2005). The skin in a hairless, protected area is lightly scarified and the virus suspension is rubbed in. Sites for vaccination include the inside of the ear pinna, the underside of the tail, or the axilla. Avoid the medial aspect of the thigh, because the infection can be spread to the lips by chewing and to the udder and teats by direct contact (Lewis 1996). Scabs appearing at the vaccination site in one to three days indicate a “take.” Monitoring this reaction as evidence of continued vaccine viability permits owners to economize by freezing leftover vaccine for later use. If some animals

32 Goat Medicine

in the herd develop vaccination scabs but others do not, a pre-existing immunity is probably responsible for absence of a take. Where a newer, parenteral vaccine is available, subcutaneous vaccination with a live cell culture vaccine avoids postvaccinal disease or excretion of the virus. Use of this vaccine every six to twelve months has been recommended in noninfected herds, and in the face of an outbreak (Mayr and Büttner 1990). In countries where capripox virus exists, vaccinating goats for capripox sometimes provides solid immunity against contagious ecthyma, whereas vaccination or natural infection with the contagious ecthyma virus provides no protection against capripox (Sharma and Bhatia 1958). There are several controversies associated with vaccination. The first is whether to recommend vaccination in a herd that is not endemically infected. The vaccine, because it is unattenuated, will introduce the disease to such a herd. In herds in which buying or showing of goats occurs regularly, vaccination prevents the occurrence of an outbreak during the show season or in milking animals. It is important to vaccinate at least six weeks before the show season so that vaccine scabs will be gone before the first show. (Presumably this procedure would increase the prevalence of subclinical carriers at shows and thereby increase the risk to unvaccinated animals in attendance.) When soremouth has appeared on the premises, it may be desirable to vaccinate all as yet unaffected goats to limit the duration of the outbreak. A program of vaccination for all young kids often in conjunction with annual revaccination of late pregnant adults is then established. Disinfection of the pens after all lesions have cleared is recommended if the owner chooses not to follow a routine vaccination program. Suitable disinfectants include 5% creolin solution, formalin, detergents, and commercially available virucidal disinfectants (Mayr and Büttner 1990). The occurrence of colostral immunity in vaccinated animals is disputed (Robinson and Balassu 1981). French enterprises that assemble kids from many sources, however, have found it advisable to pay a premium for kids from vaccinated dams. This is because vaccination of the dam seems to be more effective than vaccination of kids at birth in preventing adverse effects of the disease on the quality of kid skins (Faure 1988). In an experimental study in Mexico, kids born to dams vaccinated (virulent vaccine) in late pregnancy were challenged by skin scarification with virulent virus. Kids younger than forty-five days old resisted challenge, whereas kids older than forty-five days developed characteristic lesions (Perez 1989). Work with sheep has suggested that vaccinating at the time of drying off is preferable to vaccinating later in pregnancy when lambs are to be raised by the ewes.

Lymphocytes migrating to the udder at the end of lactation produce antibodies in the milk that may protect the lips and mouth of nursing lambs (Le Jan et al. 1978). Capripox The malignant pox diseases of sheep, goats, and cattle are not host-specific, although they show host preferences. Strains can be distinguished by restriction endonucleases but not by several serologic tests (Black 1986). Currently all strains are included in the Capripox genus of poxvirus. Etiology and Pathogenesis Capripoxviruses are distinct from parapoxviruses. They are acid-labile and sensitive to lipid solvents. Malignant sheep and goat pox infections occur in the Middle East, Far East, and Africa (Davies 1981). A benign form of goat pox has been reported from California (Renshaw and Dodd 1978) and Scandinavia (Bakos and Brag 1957) but the agents involved were not confirmed to be capripox viruses (Committee on Foreign Animal Diseases 1998). Skin lesions and scabs are major sources of virus. The virus resists desiccation and may survive in scabs for at least three months. Transmission is often through skin abrasions or by inhalation, with an incubation period of three to eight days. Viremia occurs, and the virus is carried to other sites in the skin, regional nodes, spleen, kidney, and lungs. The virus is excreted from skin lesions and in nasal exudates and milk. Night herding (congregating herds at night for protection) and stabling favor spread of the disease. Wild ungulates are not thought to serve as reservoirs. Clinical Signs The severity of signs varies with the strain of capripox. Young animals are most severely affected. Early signs include rhinitis, conjunctivitis, and pyrexia 104° to 107.6°F (40° to 42°C). The animals stand with arched back and are anorectic. Cutaneous lesions (reddish macules and papules, 0.5 to 1.5 cm diameter, Figure 2.7) and lesions on the external nares and lips and within the mouth appear one or two days later. Skin lesions persist for four to six weeks. In some outbreaks, vesicular lesions of the skin coalesce. Oral lesions on the tongue and gums tend to ulcerate. Regional lymph nodes may be enlarged up to eight times their normal size (Committee on Foreign Animal Diseases 1998). Animals that die frequently have lesions in the lungs and alimentary tract. The hair is erect over skin lesions, the skin is thickened, and crusts of exuded serum form on the surface. Healing may leave an ulcer and then a permanent scar after the full skin thickness sloughs. Damage to hides causes important economic losses.

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33

eosinophilic intracytoplasmic inclusions, vasculitis, thrombosis, and necrosis (Davies 1981). Control

Figure 2.7. Early macules of capripox infection on the skin of an experimentally infected sheep. (Courtesy National Veterinary Services Laboratories, Ames, Iowa.)

When the disease first enters a susceptible flock, morbidity may be more than 75%, and 50% of affected animals die. Mortality may increase to 100% in kids or when superimposed on other virus infections such as peste des petits ruminants. The morbidity rate is lower in endemic flocks. Some animals convert serologically without development of clinical signs. European breeds are generally more severely affected than native breeds (Karim 1983; Kitching 1986). There is also a nodular form (“stonepox”) in sheep and goats that resembles lumpy skin disease of cattle (also caused by a capripox) (Patnaik 1986). Vesicles and pustules are absent and there is no crossimmunity with more typical strains of goat pox or with contagious ecthyma. The virus is present in blood and skin throughout the course of the disease, which is often fatal (Haddow and Idnani 1948). In the benign goat pox form, vesicles and pustules develop from papules on the lips and udder (and sometimes on the perineum and inside of the thigh). Pock lesions heal in five to eight weeks, leaving behind permanent scars. Goat pox, like contagious ecthyma, has been considered to be a zoonotic disease (Bakos and Brag 1957; Sawhney et al. 1972), but more recent authors dispute this (Committee on Foreign Animal Diseases 1998). Diagnosis Capripox is most likely to be confused with contagious ecthyma because lesions may be limited to the lips, oral mucous membranes, or udder. Electron microscopy (Hajer et al. 1988) and serologic tests (such as immunodiffusion and serum neutralization) readily differentiate capripox from the parapoxvirus of contagious ecthyma. Histopathology reveals large

Import restrictions covering animals and animal products from endemic areas are required to avoid introduction of this disease to non-infected regions. Quarantine and slaughter of diseased and contact animals would be recommended if introduction occurred. A carrier state has not been documented to occur. Prophylactic vaccination reduces morbidity in endemic (often nomadic pastoral) regions. Most trials have shown excellent cross-protection with various strains of sheep and goat pox (Davies 1981). Live, attenuated vaccines (using a mild strain) are preferred but difficult to distribute (Kitching 1986). An experimental subunit vaccine reduced the severity of signs without risking introduction of the disease (Carn et al. 1994). A recombinant capripoxvirus vaccine has been produced that protects goats against peste des petits ruminants as well as against capripox (Romero et al. 1995). Use of autogenous vaccines may increase the incidence of disease (Das et al. 1978). Contagious ecthyma vaccines do not protect against goat pox. Miscellaneous Virus Infections As already discussed under the heading of pruritus, goats with rabies or pseudorabies may show skin lesions that result from severe pruritus. These conditions are discussed in Chapter 5. Scrapie in goats (also discussed under neurologic diseases in Chapter 5) may be pruritic, as demonstrated by biting and rubbing at the legs, flanks, lumbar region, and neck, and by alopecia in these areas (usually without scab formation). The clinical course of scrapie may last three to four months (Hadlow 1961; Brotherston et al. 1968; Harcourt and Anderson 1974). Peste des Petits Ruminants Peste des petits ruminants (PPR) is a morbillivirus infection that causes serious losses in sheep and goats throughout its range (Committee on Foreign Animal Diseases 1998). The major clinical signs of stomatitis, enteritis, and pneumonia are described in the appropriate chapters. During early stages of the disease, the lips are edematous and brown scabs cover eroded and ulcerated epithelium. Goats that survive the acute phase of the disease may develop labial scabs that persist up to fourteen days; histologically, acanthosis and hyperkeratosis are evident. Necrotic epithelium is infiltrated with degenerating neutrophils. There is no papilliform proliferation or ballooning degeneration typical of contagious ecthyma, although lesions are grossly similar (Whitney et al. 1967; Abraham et al. 2005). Syncytial multinucleated giant cells and

34 Goat Medicine

eosinophilic cytoplasmic inclusions may be seen in the epithelium (Çam et al. 2005). Goats that are vaccinated with inactivated vaccine (Nduaka and Ihemelandu 1975) or that are re-exposed to PPR after recovery from the virus also develop labial scabs that heal in about ten days (Ihemelandu et al. 1985). In these animals, histology reveals proliferation of macrophages and lymphocytes, suggesting an immune response. Bluetongue Bluetongue is a disease of sheep and cattle caused by an orbivirus that has at least twenty-four serotypes and is spread by Culicoides insects. Signs in sheep include fever, stomatitis, coronitis, and birth of lambs with congenital brain anomalies. Goats are susceptible to bluetongue in that viremia and fever occur and antibodies develop (Luedke and Anakwenze 1972; Backx et al. 2007), but overt clinical signs are rarely seen or described in goats in the United States. During an outbreak in cattle in Israel, two Saanen goats were found with swollen lips and marked salivation (Komarov and Goldsmit 1951). During the recent outbreak of bluetongue in northwestern Europe, a small number of goats developed edema of the lips and head, small scabs on the nose and lips suggestive of mild contagious ecthyma, and erythema of the udder skin (Dercksen et al. 2007). Goats may serve as a natural reservoir for the bluetongue virus (Erasmus 1975). Virus isolation and serology help to distinguish bluetongue from foot and mouth disease, rinderpest, and peste des petits ruminants. Bluetongue is discussed in detail in Chapter 10. Caprine Herpesvirus Experimental inoculation of kids with a herpesvirus isolate has produced vesicles, ulcers, and crusts on the muzzle and feet (Waldvogel et al. 1981). Ulcers also occurred in the mouth, esophagus, rumen, and intestines. In one naturally occurring outbreak, numerous foci of necrosis and hemorrhage were found in the skin of a single kid (Mettler et al. 1979). Any histologic finding of acidophilic intranuclear inclusion bodies in epithelial cells suggests the possibility of herpesvirus infection. The disease is discussed in Chapters 12 and 13. Foot and Mouth Disease (FMD) The picornavirus that causes FMD is a very important and exceedingly contagious disease of cattle in South America, Europe, Africa, and Asia, but is currently absent from the United States, Canada, and Australia. Signs in cattle include fever, stomatitis with vesicles and bullae, anorexia, agalactia, and a very prolonged convalescence. The disease in sheep and goats is usually mild, and only important in that these animals and meat from them may transmit the disease

to cattle. However, during outbreaks of foot and mouth disease, other (often idiopathic) oral lesions can cause great concern to regulatory authorities, at least in sheep (Watson 2004). Lameness is often the most pronounced clinical sign in goats; vesicles or bleeding ulcers may be found in the interdigital space or at the coronary band (McVicar and Sutmoller 1968; Mishra and Ghei 1983). Goats are routinely vaccinated in endemic regions. The disease is discussed in detail in Chapter 4. Vesicular Stomatitis Vesicular stomatitis is a rhabdovirus disease primarily affecting horses, cattle, and swine, and limited to the Western Hemisphere. Typical signs in these species are oral vesicles and ulcers, salivation, coronitis, and teat lesions. Regulatory officials should be notified so that the disease may be differentiated from foot and mouth disease. The epidemiology is poorly understood, but may include insect vectors such as sand flies (Lutzomyia) and black flies (Simulidae) (Committee on Foreign Animal Diseases 1998). Goats are considered to be resistant, but according to unpublished reports, vesicular stomatitis in goats has been accompanied by vesicles at the commissures of the lips, which must be differentiated from early lesions of contagious ecthyma.

BACTERIAL DISEASES Secondary bacteria, especially staphylococci, commonly invade almost any skin lesion on a goat. Thus, other etiologies should be ruled out before assuming that bacteria isolated from the surface of a lesion are causative. Other organisms, such as Corynebacterium pseudotuberculosis and Dermatophilus congolensis, are usually significant if present. Foot rot, an interdigital dermatitis caused by Dichelobacter and Fusobacterium spp., is discussed in Chapter 4. Staphylococcal Dermatitis Staphylococcal skin infections are common in goats and may be primary or secondary. The bacteria are also normal skin flora. In one Spanish study, 346 strains of staphylococci were isolated from axillary skin or udder of 133 healthy goats, and 21% of these isolates were coagulase-positive (S. aureus and S. hyicus) (Valle et al. 1991). Etiology Impetigo is a superficial pustular dermatitis that does not involve hair follicles. Staphylococcal folliculitis is an infection and inflammation of hair follicles (Scott 1988). The species involved often has not been reported. Staphylococcal species isolated from goats with skin disease include S. intermedius, S. aureus, S. chromogenes, and S. hyicus (Scott 1988; Andrews and

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Lamport 1997; Mahanta et al. 1997). Species identification is not a good predictor of antibiotic sensitivity (Biberstein et al. 1984). Clinical Signs and Diagnosis The primary lesion is a nonfollicular or follicular papule that develops into a pustule. Lesions may enlarge or coalesce, discharge purulent or serosanguinous exudate, and become encrusted (furunculosis, Scott 2007). Alopecia and scaling are prominent in the chronic or healing stage. Multiple small pustules of impetigo frequently appear on the teats and udder (Figure 14.3) or perineum and underside of the tail. Because these pustules may be preceded by vesicles and followed by scabs, they may be confused with lesions of contagious ecthyma (Smith 1981). Direct smears show degenerate neutrophils with phagocytosed cocci (Scott 2007). When lesions remain localized they are relatively benign and self-limiting, except that lesions on the teats predispose to staphylococcal mastitis. Fly bites on the udder (fly worry) are said to resemble a staphylococcal infection but to be more pruritic (Matthews 1999). In some goats, the infection becomes general, involving the skin of the abdomen, inner thighs, and even the neck and back. Other distributions are possible, especially if the staphylococci are secondary to another condition, such as chorioptic mange. Periocular alopecia and crusts comprise yet another possible manifestation (Scott 1988). Confusion with mycotic infections or nutritional deficiencies is possible. A presumptive diagnosis is often based on inspection alone. Gram stains and cultures document the presence of staphylococci, while evaluation of skin biopsy specimens should help to rule out other diseases that might have been primary and still require therapy. Treatment and Prevention Localized lesions on the udder may be washed with an iodophor or chlorhexidine shampoo, dried, and then coated with an antiseptic or antibiotic ointment. Affected does should be milked last. Single service paper towels and attention to hand washing by the milker decrease the risk of spread to other does. Rubber gloves protect against transmission of infection to humans. Similar treatment of lesions around the tail is possible, but these seem to be less important and frequently heal spontaneously. If a generalized infection is suspected, culture of the organism and determination of antibiotic sensitivity are recommended. Systemic antibiotic treatment (one to two weeks of therapy) may start with penicillin, pending results of sensitivity testing. As the concern over methicillin-resistant staphylococci increases in both veterinary and human medicine, it is very impor-

35

tant for the practitioner to remember that many of the antibiotics used to control these infections in other species are forbidden by law in all sheep and goats in the United States, because of their status as food animals. Thus, no matter what the laboratory reports for a sensitivity pattern, chloramphenicol, fluoroquinolones such as enrofloxacin, and glycopeptides such as vancomycin are absolutely forbidden in all goats. Autogenous bacterins may be tried for control of chronic or epizootic infections (Scott et al. 1984a), but bacterins have not received scientific evaluation in caprine dermatology. Dermatophilosis Dermatophilosis, also known as streptothricosis, is a common skin infection in goats worldwide. Cattle, sheep, horses, various wildlife species, and humans are also affected (Stewart 1972; Hyslop 1980). Etiology Dermatophilus congolensis is a Gram-positive, pleomorphic, facultative anaerobic actinomycete. It produces motile zoospores which invade the skin. Pathogenesis Dermatophilus congolensis may survive in soil or in dust on an animal’s hair coat during dry weather. It is introduced into the epidermis following injuries of any sort, including those caused by tick bites and thorny vegetation. Its life cycle is activated by moisture (Bida and Dennis 1976). Outbreaks often occur during periods of heavy rain or high humidity (Mémery and Thiéry 1960; Yeruham et al. 2003). Clinical Signs Several localizations of the disease have been reported. Ears are commonly involved, especially in young kids (Larsen 1987). Tiny wart-like scabs first appear on the inner hairless surface of the ear pinna. They are easily rubbed off, exposing dry, circular, lightcolored areas beneath. Raised scabs with matted hairs form on the external portions of the ears and are more tightly attached (Figure 2.8). The lesions are nonpruritic and benign and last two to three months in kids if not treated (Munro 1978). Other affected areas of the body include the nose, muzzle, feet, scrotum, and underside of the tail (Mémery 1960; Yeruham et al. 2003; Loria et al. 2005; Scott 2007). These areas of skin frequently are exposed to moisture or mild abrasion from vegetation. Thick proliferative crusts may be mistaken for lesions of contagious ecthyma (sore mouth) (Tiddy and Hemi 1986). In fact, the simultaneous presence of both diseases has been reported in splenectomized kids (Munz 1969, 1976) and in Yaez goats, a cross between domestic goats and wild ibex (Yeruham et al. 1991). The dry

36 Goat Medicine

used. The organisms in smears also fluoresce under ultraviolet light after staining with acridine orange (Mathieson 1991). Fluorescent antibody techniques have been used for rapid identification of the organism in smears of exudate (Pier et al. 1964). In dry lesions, skin biopsy is necessary to demonstrate the organism. In addition to superficial exudate, there is hyperkeratosis and infiltration of the epidermis and hair follicles with neutrophils. Bacterial filaments in the biopsy sample are periodic acid Schiff (PAS) positive (Loria et al. 2005). Culture of the organism by a diagnostic laboratory will also confirm the diagnosis, but this is best done under microaerophilic conditions with increased carbon dioxide (Scott 1988). Scabs are ground up in saline and cultured at once and also after twenty-four hours at room temperature. A medium that selects for Gram-positive organisms (such as colistin-nalidixic acid medium) is helpful. Tiny gray adherent colonies composed of branched mycelia may be visible after forty-eight hours and should then be subcultured; it is common for the original plate to be rapidly overgrown by contaminants. Several serologic tests have been used to identify antibodies against D. congolensis. The purpose was to potentially monitor the prevalence of exposed animals. The tests have included passive hemagglutination (which showed 23% of slaughtered goats in a Nigerian study to be seropositive) (Oyejide et al. 1984) and radial immunodiffusion (Makinde 1980). Figure 2.8. Dry scabs typical of dermatophilosis on the external surface and margin of the ear. (Courtesy Dr. M.C. Smith.)

crusts, scaling, and alopecia of healing or chronic lesions resemble ringworm. Secondary bacterial infections (e.g., staphylococci, corynebacteria, Fusobacterium necrophorum) are to be expected and may lead to pruritus or pain. Sometimes the entire dorsum of the goat is involved with lesions clinically resembling rain scald in horses; continuous exposure to wet weather presumably is an important etiologic factor (Bida and Dennis 1976; Scott et al. 1984a). Damage to hides can be extensive. Suppurative lymphadenitis has been reported in Beetal goats from which D. congolensis was demonstrated by smear and culture (Singh and Murty 1978). Diagnosis The diagnosis can be confirmed in several ways. When lesions are moist, an impression smear of the underside of a scab reveals Gram-positive branching filaments either unsegmented or in railroad track arrangements of two to eight parallel rows of cocci (Scott 2007). Giemsa or Diff Quik® stain may also be

Therapy and Prevention Penicillin-streptomycin was commonly recommended for dermatophilosis in individual animals in the past, but this product is no longer available in the United States. Tetracycline is also effective. Where feasible, shelter from the rain and bathing (iodophors, 2% to 5% lime sulfur) and grooming to remove crusts should be recommended. Improved nutrition and control of external parasites (especially ticks) are also desirable for treatment and prevention. Cleansing thick crusts with hydrogen peroxide will help to control secondary anaerobic infections. Brushes should be disinfected before being used on other animals. Goat handlers should also be warned that people are occasionally infected with this organism. Carrier animals appear to be the reservoir for the agent, but the organism can also survive for many months in the environment. Vaccination against dermatophilosis has not been successful (Bida and Dennis 1976), and recovery does not appear to provide immunity. Corynebacterium pseudotuberculosis Corynebacterium pseudotuberculosis is usually associated with lymph node enlargement (caseous lymphadenitis) and is discussed in detail in Chapter 3. However,

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small nodules and draining tracts in the skin sometimes occur in goats (Scott 2007) and may be a source of infection to others. Diagnosis is made by culture and by skin biopsy, which reveals a tuberculoid granulomatous reaction (Scott 1988). Affected animals should be isolated or culled. Actinobacillosis, Actinomycosis, and Protothecosis Actinobacillosis, a suppurative to granulomatous disease of sheep caused by Actinobacillus lignieresii, has not been well documented in goats. Diagnosis is based on demonstration of cheese-like granules less than 1 mm in diameter in pus or by aerobic or anaerobic culture of the organism. In direct smears, club-like bodies radiate from the center of the granules and crushing reveals small Gram-negative bacilli. Rinsing and culturing the granules, rather than simply swabbing a fistulous tract, is recommended to avoid overgrowth with secondary bacteria (Scott 1988). Treatment, at least for sheep, typically involves sodium iodide (20 mg/kg of sodium iodide as a 10% solution intravenously or subcutaneously) weekly for four to five weeks and streptomycin (20 mg/kg/day) for five to seven days. A case of pyogranulomatous dermatitis has been reported on the udder of an aged dairy goat. A diagnosis of Actinomyces sp. was based on the appearance of the organism in Gram stained smears and the presence of sulfur granules. Raised knot-like lesions were yellowish brown or reddish black and abscesses extended into the parenchyma of the udder. Udder amputation was the proposed therapy but the goat died first (Hotter and Buchner 1995). A single case of pyogranulomatous dermatitis around the nares caused by a Prototheca sp. has been reported from a mature goat in Brazil (Macedo et al. 2008). Ulcerated nodules contributed to inspiratory dyspnea and weight loss. Oval to spherical, nonbudded, walled sporangia typical of this algal-like organism that lacks chlorophyll were demonstrated in histologic section. Treatment was not attempted, but various antifungal agents are used to treat human and canine cutaneous protothecosis.

FUNGAL DISEASES Ringworm and other fungal infections usually occur when nutrition or environmental conditions are inadequate. Crusting, alopecic skin disease should not be assumed to be of fungal origin without laboratory confirmation. Ringworm Etiology A variety of dermatophytes have been cultured from ringworm in goats. These include Microsporum

37

canis and M. gypseum, Trichophyton mentagrophytes, T. schoenleinii and T. verrucosum, and Epidermophyton floccosum (Philpot et al. 1984; Scott 1988). Clinical Signs and Diagnosis Lesions in goats consist of alopecia, scaling, erythema, and crusts. They typically involve the face, external ears, neck, or limbs, and may be annular in shape (Scott 2007). Pruritus is not usual, but has been reported (Chineme et al. 1981). Microscopic examination of hairs and keratin from the periphery of an active lesion (as described above) may reveal ectothrix invasion of hair shafts. Species identification requires culture and examination of both colony and microscopic morphology. Treatment and Prevention Young animals (Pandey and Mahin 1980) or those living in a dark, damp, dirty environment, or those with debilitating nutritional or infectious diseases are most at risk for developing ringworm. Management changes, then, may be required to control an outbreak in goats. Most cases of dermatophytosis in large animals regress spontaneously in one to four months. Thus, although oral griseofulvin has been reported to be effective in treating ringworm in goats at 25 mg/kg/day for three weeks (Chineme et al. 1981), this expensive therapy is usually not justified (Scott 1988). Topical treatment does reduce contamination of the environment and the risk of spread to other animals or man. People handling infected goats should take precautions to avoid contracting the infection themselves. Lime sulfur (2% to 5%), iodophors, and 0.5% sodium hypochlorite as total body sprays daily for five days and then weekly are recommended for ringworm (Scott 1988). Captan (3%) is effective (Scott 1988), but not approved in the United States for foodproducing animals. Topical thiabendazole paste or iodine ointments or products for athlete’s foot (tinea pedis) can be used on small lesions. All in-contact animals should also be treated, and the environment disinfected with sodium hypochlorite if possible. Pens that have previously housed young cattle with ringworm should be thoroughly disinfected before goats are introduced. Yeast Infections Budding yeasts are occasionally present in large numbers in samples taken from goats with alopecia, scaling, and crusting (Scott 1988). In most instances they probably represent secondary opportunists (Reuter et al. 1987). A Malassezia (Pityrosporum) species was suspected in milking goats with annular lesion on the teats and udder, based on PAS-positive organisms seen in the epidermis (Bliss 1984). A Malassezia species,

38 Goat Medicine

possibly M. pachydermatis, was isolated from an adult goat with chronic greasy, seborrheic lesions over the trunk but sparing the extremities (Pin 2004). The animal responded rapidly to weekly chlorhexidine-containing shampoo and topical enilconazole. In a third reported case, Malassezia slooffiae in hyphal and yeast forms was identified in the skin of an adult Pygmy goat with a one-month history of weight loss and extensive alopecia and crusting of the body and limbs (Uzal et al. 2007). Goats with yeast infections should be evaluated for chronic wasting diseases, with special attention given to possible nutritional deficiencies (e.g., protein, trace minerals). Miscellaneous Fungal Infections Peyronellaea glomerata, ordinarily a saprophyte on decaying vegetation, has been isolated from hyperkeratotic ear lesions on goats (Dawson and Lepper 1970). Brown septate hyphae were abundant in the stratum corneum in skin biopsies. Several fungal species can produce mycetomas (granulomatous subcutaneous lesions with draining sinuses and granular fungal elements) in goats (Gumaa et al. 1978; Gumaa and Abu-Samra 1981). Proliferation of the periosteum of underlying bone may be marked. Cryptococcus neoformans, a rare cause of pneumonia and mastitis in goats, has also caused ulcerated granulomas in the skin of the head of one goat and in the nasal passage of another goat in Australia (Chapman et al. 1990). The diagnosis was made by demonstrating the oval or budding encapsulated organisms in smears, histopathology samples, or culture.

PARASITIC DISEASES Many external parasites, including lice, ticks, and mange mites, infest goats. Each is discussed separately, but there is an extensive overlap in the realm of therapy. For the convenience of the reader, some of the chemicals effective against external parasites are listed in Table 2.1 (Scott 1988; Bowman 2003). Lice All species of goat lice complete their life cycle on the host and are quite host-specific. Eggs (nits) are attached to hairs and hatch in five to eighteen days. The nymphal stages look like tiny adults; young lice mature fourteen to twenty-one days after hatching. Bovicola (Damalinia) ovis, the sheep louse, can become established on goats, and thus goats may be a source for reinfesting sheep during louse control programs (Hallam, 1985). Clinical Signs and Diagnosis Bloodsucking lice (order Anoplura) have relatively narrow heads with piercing mouth parts. Two species

Table 2.1. Some chemicals used for control of external parasites of goats. Chemical

Concentration and form

Amitraz (L) Coumaphos (L) Crotoxyphos (L) Dichlorvos (L) Eprinomectin (L) Fenvalerate Fipronil

0.025%–0.05% spray 0.25% spray, 0.5% dust 0.25%–1% spray, 2% dust 0.5%–1% spray 0.5–1 mg/kg pour-on 0.05% dip 0.29% spray (not labeled for food animals) 20–40 mg/100 kg subcutaneous injection 2%–5% dip 0.06% spray, 0.03% dip 0.5% spray, 5% dust 0.5%–1% spray/dip, 5% dust 0.05% spray, 0.5% spot treatment 0.15%–0.25% spray/dip 0.2% spray/dip

Ivermectin Lime sulfur (L) Lindane Malathion Methoxychlor Permethrin (L) Phosmet Trichlorfon

Note that many of these products are not licensed for goats in most countries. Chemicals designated by (L) are generally appropriate for dairy animals. Product labels should be read for instructions and safety precautions.

have been reported from goats in the United States: Linognathus stenopsis (females 2.75 mm long, males 2.2 mm) and Linognathus africanus (distinguished by bulging posterolateral margins of the head; females 2.15 mm, males 1.65 mm). They are bluish-gray and infest both Angoras and the other breeds of goats (Price and Graham 1997). Blood loss and secondary bacterial skin infections may occur in addition to pruritus. Heavy infestations may kill kids. Biting lice (order Mallophaga) have broader chewing mouth parts. They are pale, small (1 to 2 mm) and more difficult to see. They provoke rubbing and scratching and can also bite through the hairs, resulting in alopecia and moderate to severe damage to Angora fleeces, depending on the louse numbers. The yellowish, hairy Bovicola (Damalinia) (Holakartikos) crassipes and the red louse Bovicola (Damalinia) limbatus are common on Angora goats, while Bovicola (Damalinia) caprae is the slightly smaller biting louse usually found on meat or dairy goats in the United States. The same goat can be infested with more than one louse species at a time (Sebei et al. 2004). Certain goats appear to have a natural resistance to biting lice, as documented during efforts to cause experimental infestations (Merrall and Brassington 1988). Diagnosis is by physical examination and demonstration of lice or nits directly or on material collected by plucking or combing. A flea comb works well to

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harvest material that can be placed in a ziplock bag for later examination with a dissecting microscope or hand lens. In one study, biting lice were concentrated in the withers area (where the goat had more difficulty grooming itself) while sucking lice were more prevalent over the brisket and shoulders (Merrall and Brassington 1988). Because lice are sensitive to elevated temperatures, their location on the body may vary with air temperature and exposure to sunlight. Populations are generally higher in winter than summer. Therapy Numerous insecticides are effective against goat lice (Moore et al. 1959; Bowman 2003), but nits are not killed. Resistance also may develop, and has been documented for permethrins (Levot 2000) but in some instances may be the result of product failure to reach the lice (Bates et al. 2000). Label directions should be followed to avoid contamination of milk and meat. Because nits are not killed by the initial therapy, treatment should be repeated at ten- to fourteen-day intervals if possible to remove young lice before they mature. Treating before kidding helps to prevent the normally rapid transfer of lice to newborn kids. In goat breeds that are shorn, and even in dairy breeds, the best results are obtained by treatment after removal of the fleece and attached nits. Products used include crotoxyphos (1% in water spray or 3% dust), coumaphos (0.25% in water spray or 0.5% dust), dichlorvos, and fenvalerate. Pour-ons are more convenient than sprays or dips, and dusts are preferred to dips in cold weather. Coumaphos (Konar and Ivie 1988) and fenvalerate pour-ons may cause milk contamination. Newer permethrins appear to be both safe and effective, with no milk or meat withdrawal requirements. In India, flumethrin pour-on at 1 mg/kg provided complete louse control on goats for more than six weeks (Garg et al. 1998). Eprinomectin as a pour-on would be safe for lactating goats but is not approved in the United States. Ivermectin, also unapproved, at 20 mg/100 kg subcutaneously, is efficacious against sucking but not biting lice; it should not be used in lactating dairy goats and this dose is likely to select for resistant gastrointestinal parasites (see Chapter 10). For pets and young kids, rotenone, flea powders labeled for cats, and even flea collars may be more convenient that commercial livestock preparations. Note that extralabel use of pesticides is not sanctioned in the United States and agricultural products containing rotenone are being withdrawn from the market. Insect hormones have been used experimentally to control lice (Price and Graham 1997). Three spray treatments of 0.1% synthetic juvenile hormone at twoweek intervals controlled biting lice for four months (Chamberlain and Hopkins 1971).

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Fleas Dog and cat fleas (Ctenocephalides spp.) sometimes infest goats in tropical regions (Obasaju and Otesile 1980, Opasina 1983) and in the United States (Konnersman 2005b). In Greece, human fleas (Pulex irritans) cause long-term infestations of dairy goats (Christodoulopoulos and Theodoropoulos 2003; Christodoulopoulos et al. 2006). The wingless, laterally compressed, 2- to 4-mm-long adult insects suck blood and cause local irritation. Fleas frequently leave their hosts. Eggs are laid on the goat or on the ground. Clinical signs include restlessness, rubbing and chewing, excoriations, alopecia, nonfollicular papules, and crusts. The fleas are easiest to find when the goat is restrained on its back. Anemia and weight loss may occur in young or debilitated animals (Fagbemi 1982). Peripheral eosinophilia and infiltration of the skin by eosinophils suggest that an allergy to flea saliva may be involved in severe cases (Yeruham et al. 1997). Treatments suggested for lice are also appropriate for fleas, but the environment and all mammalian hosts must be treated. Keds Melophagus ovinus is a wingless blood-sucking fly (six legs) that infests both sheep and goats. The parasite is 6 to 7 mm long and easily seen, resembling a tick. The entire life cycle is completed on the host in five weeks or longer. The parasite causes skin irritation and blood loss, but damage to hides may have greater economic significance. Shearing removes many keds. The insecticides used for louse control are also effective against keds. Biting Flies, Gnats, and Mosquitoes Black flies (Simuliidae) may attack goats in swarms in the spring in areas of running water. Insecticides work poorly for repelling these pests, and stabling during the day may provide the most relief (Gnad and Mock 2001). Stable flies (Stomoxys calcitrans) and horse flies and deer flies (Tabanidae) also inflict painful bites. Residual topical permethrin products will provide some relief. Culicoides gnats are additional bloodsucking pests that swarm in the afternoon and evening. They are reported to cause significant skin lesions on small ruminants (Gnad and Mock 2001) but these lesions are not well described. Individual animals may become hypersensitized to the saliva of the gnats. Culicoides gnats are important vectors for bluetongue virus and bunyaviruses. Mosquitoes take blood meals from goats, as from other mammals. Control efforts are usually directed at eliminating stagnant water. The diagnosis of insect hypersensitivity is usually presumptive in an animal that develops seasonal pruritus and self-excoriation (Figure 2.9). If insect

40 Goat Medicine

Figure 2.9. Apparent recurrent insect hypersensitivity in a buck that showed severe pruritus and self-excoriation in the early spring in New York. (Courtesy Dr. M.C. Smith.)

repellants and stabling do not control the signs, injectable dexamethasone can be used in nonpregnant goats. Cutaneous Myiasis The New World screwworms Cochliomyia (previously Callitroga) hominivorax in North, Central, and South America are the maggots of flies that must deposit their eggs in wounds or at body orifices rather than in dead carcasses. The species was eradicated from the United States in 1966 by the use of sterile males. The parasite is reportable in the United States and briefly entered Texas from Mexico in 1982; it also arrived on assorted imported animals and people in later years (Alexander 2006). One case involved a larva found on an Angora goat in Texas in 1998, following a hurricane (AVMA 1999). Shearing, dehorning, castration, and ear marking wounds and tick bites are common targets, as are the mouth and navel of newborns. As a complication to the presence of maggots in foul-smelling, pruritic lesions, toxemia or septicemia may kill the goat. Wounds should be debrided and treated with a topical insecticide such as malathion or coumaphos in ointment form. Fly repellents prevent repeat attacks, and antibiotics are indicated if the animal is systemically ill. Injectable avermectins have prevented establishment of screwworm larvae in wounds of calves (Alexander 2006). Dicyclanil, an insect growth regulator, shows promise for long-term prophylaxis of this and other forms of myiasis (Sotiraki et al. 2005). Chrysomya bezziana is known as the Old World screwworm fly and has been documented to cause myiasis in goats on the Arabian peninsula (Spradbery et al. 1992; Abo-Shehada 2005). Although this fly has not yet been transferred to the Western Hemisphere,

modern transportation certainly makes translocation possible. Wohlfahrtia magnifica is an important cause of primary myiasis in Asia (Iran to Mongolia) and the Mediterranean area. Infestation of goats increases with age, and the body regions most commonly struck are the genitalia and the extremities (Ruiz-Martinez et al. 1991). Clinical signs include inflammation, pruritus, apathy, and weight loss (Ruiz-Martinez et al. 1987). A variety of blowfly larvae (calliphorine myiasis) can be found in the same wounds that attract screwworms and are differentiated by close examination of larval anatomy. Bacterial activity (fleece rot, fecal contamination of skin, urine scald) also can make intact skin attractive to these flies. Foul-smelling ulcers are filled with maggots. Cleansing of the wound with a mild solution of pine oil is helpful, because most of the maggots will come out of their holes and drop to the ground. Insecticides, fly repellents, and antibiotics are applied as for screwworms. Warbles Przhevalskiana (Hypoderma) silenus is a warble fly that naturally infests goats in Mediterranean countries and Asia. Hypoderma aeratum is reported to parasitize goats in Cyprus, Crete, and Turkey, while H. crossi infests goats in the dry, hilly regions of India (Soulsby 1982). Recent authors have suggested that these are all one species (Otranto and Traversa, 2004). Hypoderma bovis and H. lineatum (warble flies of cattle) have not been documented to infest goats (Colwell and Otranto 2006). Pathogenesis and Clinical Signs Adult P. silenus flies lay eggs on the hairs of the legs and chest in spring. It is believed that the larvae migrate by a direct subcutaneous route to the back rather than passing through the esophagus or spinal cord (Otranto and Puccini 2000). First-stage larvae appear under the cutaneous trunci muscle, which becomes necrotic and infiltrated by neutrophils. The larvae penetrate the overlying muscle and skin and molt into the second instar. Larval debris and cellular infiltrates accumulate, and a wall of granulation tissue forms around each larva (Cheema 1977), which is typically 10 to 12 mm long. Third-stage larvae drop to the ground to pupate. As many as 150 larvae have been found in a single goat (Prein 1938). In a slaughterhouse survey in Turkey, 53% of 1,049 goats examined were infested with P. silenus. Larval numbers ranged from one to fifty-two per infested animal with an average of seven (Göksu 1976). Sometimes the hide has the appearance of a sieve. The holes in the hides cause tremendous losses in the fine leather industry in Iran, where 93% of goats in a slaughterhouse study were infested (Rahbari and Ghasemi 1997).

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Therapy Ivermectin, at dosages of 5 to 20 mg/100 kg, has been effective in killing all instars of the warbles (Tassi et al. 1987; Yadav et al. 2006). Even microdoses of ivermectin (0.5 mg/100 kg as injectable, 1 mg/100 kg as pour-on) are highly efficacious and result in minimal milk contamination (Giangaspero et al. 2003). Modern systemic insecticides are often not available in countries where this parasite abounds. Shepherds have been taught to remove warbles during the winter months. Ticks Ticks are important ectoparasites throughout the world. Etiology A discussion of the life cycles and identification of the many species reported to infest goats is beyond the scope of this book; readers should refer to standard parasitology texts (Soulsby 1982). Some important species are listed in Table 2.2 and species occurring in the United States have been reviewed by Gnad and Mock (2001). Soft ticks belong to the family Argasidae and feed repeatedly on their hosts. Hard ticks, family Ixodidae, have a shield on the dorsal surface and feed only once during each stage. Larval ticks have six legs, while nymphal and adult ticks have eight legs. Ticks are referred to as one-host, two-host, or three-host,

41

according to whether they drop off the host to molt between larval and nymph stages and between nymphal and adult stages. Ticks are not especially host-specific (Scott 1988). Clinical Signs and Diagnosis The attachment site varies with the tick species (Baker and Ducasse 1968), and may show papules, pustules, or wheals initially, with crusts and ulcers forming secondarily. Demonstration of the tick will make the diagnosis, but skin biopsy to demonstrate embedded tick mouth parts may be necessary in persistent, nodular lesions. Secondary bacterial infections and myiasis are possible. Ticks such as Amblyomma hebraeum and Rhipicephalus glabroscutatum attach to feet, especially between the claws, and may predispose to foot abscesses (MacIvor and Horak 1987). Damage to hides is important. Other important consequences are blood loss and the transmission of very serious diseases such as anaplasmosis, babesiosis, heartwater, theileriasis, and tick-borne fever. Tick paralysis may also occur. Pituitary abscess has been associated with attachment of ticks beneath backswept horns of Boer goats in South Africa (Bath et al. 2005). These conditions are discussed elsewhere in this book. Therapy Simple extraction of the tick is recommended when ticks and goats are few. A device with a slit that is

Table 2.2. Some ticks of importance to goats. Tick Argasidae: soft ticks Otobius megnini Ornithodorus spp. Ixodidae: hard ticks Ixodes ricinus

Distribution

Importance

North and South America, southern Africa, India United States, Asia

Causes irritation and blood loss in ears

Europe

Ixodes pilosus Ixodes rubicundus Boophilus decoloratus Boophilus microplus Rhipicephalus appendiculatus

South Africa South Africa Ethiopia Tropics Africa

Rhipicephalus bursa Rhipicephalus haemaphysaloides Haemaphysalis punctata Amblyomma hebraeum Amblyomma variegatum Amblyomma cajennense Dermacentor spp.

Africa and southern Europe India Europe, North Africa Africa Africa and Caribbean North and South America Worldwide

Transmits Q fever, Theileria, and Anaplasma Transmits tick-borne fever, louping ill, tick paralysis Does not cause paralysis Tick paralysis Transmits Borrelia, Theileria Tropical cattle tick Attaches in ears and beneath tail; transmits Nairobi sheep disease Transmits Theileria ovis, Babesia ovis Transmits tick-borne fever Transmits Babesia motasi, Theileria Transmits heartwater Transmits heartwater Tick paralysis (Brazil) Sometimes causes tick paralysis

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placed around the mouthparts and then rotated works better than tweezers and direct traction for manual removal (Zenner et al. 2006). A large variety of sprays, dips, and pour-ons (see Table 2.1) will reduce the population of ticks and provide temporary protection. The use of insecticides can be reduced by local spraying or hand-dressing of the body area (ear canal, perineum) where ticks are located (Baker and Ducasse 1968). Systemic ivermectin may also prevent complete engorgement (Wall and Shearer 2001). Residues in meat, milk, and the environment are a concern, as is the possible development of resistance of ticks to insecticides (Stampa 1964) and of gastrointestinal strongyles to ivermectin. Control Total eradication of a tick species is usually very difficult. A reduction in tick numbers is achieved by several applications of insecticide at two- to threeweek intervals. Two- and three-host ticks require treatments throughout the tick season, while one-host ticks are more likely to be on the host and therefore killed with one or two treatments. Amitraz has been used as a pasture spray to decrease tick burdens (Harrison and Palmer 1981). In certain circumstances, burning the pasture or cultivating the land may aid in tick control. Sarcoptic Mange The mite that causes sarcoptic mange (scabies) in goats has been referred to as either Sarcoptes rupicaprae or a goat-specific strain of Sarcoptes scabiei. It tunnels through the epidermis and feeds on tissue fluids (Scott 1988). Experimental infection of desert sheep with a goat strain of Sarcoptes scabiei has been documented (Ibrahim and Abu-Samra 1987) and probably occurs naturally when the two species are raised together. Molecular analyses suggest that all sarcoptic mites belong to a single, heterogeneous species (Zahler et al. 1999). Human infection can occur from handling affected goats (Menzano et al. 2007). Clinical Signs The condition is reported to begin with the appearance of small pruritic nodules, especially on the head, several weeks after contact with another infested goat or chamois (Menzano et al. 2007). The skin disease seems to be self-limiting in some goats, while others develop extensive severe dermatitis around the eyes and ears and on the neck and thorax, inner thighs, udder, and scrotum. Hyperkeratosis and alopecia are accompanied by self-excoriation and restlessness. The thickened skin is wrinkled and fissured (Abu-Samra et al. 1981; Kambarage 1992) and may harbor a secondary bacterial infection. Severely affected goats lose weight

and have prominent peripheral lymph nodes. Some deaths occur (Zamri-Saad et al. 1990; Menzano et al. 2007). The value of the hide is markedly decreased. Diagnosis Confirmation of the diagnosis usually requires deep scrapings at the margin of lesions; the mites are identified by the presence of long unjointed pedicels on the pretarsi. Even if no mites are seen in multiple scrapings, a biopsy report of eosinophilic dermatitis and tunnels should indicate a presumptive diagnosis of sarcoptic mange (Deorani and Chaudhuri 1965; Scott 1988). In some chronic cases, diagnosis is made by response to therapy. Local regulations may require reporting a positive diagnosis to government authorities. Therapy Treatment of lactating animals can be accomplished with repeated (perhaps five to ten) applications of lime sulfur solution every five to seven days. Two treatments of 0.05% amitraz seven to ten days apart are recommended for controlling scabies in dairy cattle in the United States, and should thus be safe for dairy goats. In nonlactating animals, many different parasiticides have been applied with some success, but relapses are common when treatment is discontinued (Jackson et al. 1983). Sprays often fail to adequately penetrate the long and thick hair coat of unshorn animals. Some animals may need antibiotics for secondary bacterial infections. More recently, ivermectin (subcutaneously) has simplified treatment, especially because the inconvenience and stress of bathing a disgruntled goat in cold weather are avoided. A cleansing shampoo is recommended to remove crusts, even if ivermectin is given. However, excellent response, including disappearance of the crusts, was achieved in Saudi Arabia when goats were treated with ivermectin (1 ml of a 1% solution per adult of unspecified weight) twice, one week apart. Live mites were recovered from treated animals for at least two weeks, but all goats yielded negative skin scrapings three weeks after the second treatment (Wasfi and Hashim 1986). In another instance, three doses two weeks apart of subcutaneous ivermectin at 0.2 or 0.4 mg/kg were effective (Zamri-Saad et al. 1990). Three treatments fourteen days apart with topical moxidectin at 0.5 mg/kg were successful in clearing a severely infected Italian goat herd of the parasite; a higher dose, more appropriate for goats, might have been more rapidly effective (Menzano et al. 2007). For the lactating animal, a single topical application of eprinomectin (Eprinex® pour-on, Merial) at 1 mg/kg (twice the cattle dose) might be preferable, because milk residues remain below the limit established for dairy cows (Dupuy et al. 2001).

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Chorioptic Mange Some authors believe that the chorioptic mange mite of goats belongs to the species Chorioptes bovis, while others consider it to be host-specific and designate it as C. caprae (Scott 1988). Epidemiology The mite lives on the surface of the skin and feeds on epidermal debris. It may exist on nonclinical carrier goats and can also survive in the environment for as long as ten weeks (Liebisch et al. 1985). This accounts for sudden occurrence of mange lesions in closed herds. Mite populations are affected by the environment, with the highest mite numbers and most severe clinical signs in cold weather. In a New Zealand study of feral goats, the prevalence of chorioptic mites was 100% in the winter, although marked lesions were found on the legs of only five of 368 goats overall (Heath et al. 1983). Clinical Signs and Diagnosis The lesions (nonfollicular papules, crusts, alopecia, erythema, and ulceration) are most commonly or initially found on the lower limbs, with occasional spread to udder, scrotum, and perineal region (Scott 2007). Pruritus, as demonstrated by stamping or chewing at the limb lesions, may be obvious, or the alopecia and crusts may appear benign (Figure 2.10). Only rarely is the dermatitis caused by Chorioptes generalized (Dorny et al. 1994). Diagnostic samples can be obtained with a flea comb or by skin scrapings; adding rotenone to the mineral oil used for collecting scrapings will prevent the escape of the mites on the way to the microscope (Scott 1988). The mites have short pedicels on their pretarsi. Zinc deficiency and bacterial skin infections are important differential diagnoses that may be present concurrently with mange.

Figure 2.10. Mild crusting and scaling on the pastern of a goat with chorioptic mange. (Courtesy Dr. M.C. Smith.)

healthy skin) has been shown to be effective against C. bovis on cattle (Barth and Preston 1988). Fipronil (Frontline® Spray, Merial) has also been advocated for goats (Konnersman 2005b). National regulations concerning milk and meat residues should be respected. Using shampoo to remove crusts and shearing of mohair will improve efficacy of externally applied acaricides. Systemic antibiotics for secondary bacterial infections and judicious use of glucocorticosteroids in apparently allergic goats are indicated in select cases.

Therapy

Psoroptic Mange

Treatment of chorioptic mange is sometimes very easy, but hypersensitivity of certain goats to the mites can lead to treatment failure and frustration. All in-contact goats should be treated simultaneously to eliminate the carrier state and the premises disinfected. Lime sulfur (four weekly, total body sprays or dips in 2% solution) is safe for lactating dairy goats. Crotoxyphos (0.25%), coumaphos (0.25%), trichlorfon (0.2%), amitraz (0.05%), and lindane (0.03%) must be applied at least twice at ten- to fourteen-day intervals. In one study, a single dip with fenvalerate (0.05%) killed all mites on Angora goats (Wright et al. 1988). Injectable ivermectin can be expected to kill many but not all of the mites, because of their superficial location. Topical application of ivermectin (0.5 mg/kg applied once to

The classification of mites of the genus Psoroptes is currently unsettled (Scott 1988; Zahler et al. 1998; Bates 1999). The proposed role of ear mites in the transmission of mycoplasma infections is discussed in Chapter 9. Etiology and Epidemiology The most commonly reported ear mite of goats is the cosmopolitan Psoroptes cuniculi. Prevalence in necropsy studies appears to be high (twenty-one of twenty-four and eight of eighteen) (Williams and Williams 1978; Cook 1981). The mite can be found in the external ear canal of kids as young as ten days old, with most kids infested by the third week (Williams and Williams 1978). In feral goats in New Zealand, the

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infestation was often unilateral and was more common in winter and in older goats (Heath et al. 1983). When it causes body mange (in parts of the world where sheep are affected with psoroptic mange), the parasite is sometimes referred to as P. caprae. The mite has long, segmented pedicels and is often visible to the naked eye. It does not burrow but feeds on tissue fluids. Prolonged survival times (as long as twelve weeks) in the environment have been reported (Liebisch et al. 1985).

ing pet goats, two treatments with injectable or oral ivermectin one to two weeks apart (20 mg/100 kg) is a rational therapy (Lofstedt et al. 1994). Instillation of several drops of an ivermectin solution into each ear canal is also effective (Konnersman 2005b). Body mange can be treated with routine acaricides (including amitraz; Harrison and Palmer 1981) as dips or sprays. Ivermectin (two injections one week apart) also has been found effective in treating psoroptic mange in goats (Wasfi and Hashim 1986).

Clinical Signs and Diagnosis

Raillietia

Clinical signs of ear mite infestation include head shaking (Dorny et al. 1994) and scratching, sometimes with alopecia of the part of the ear repeatedly brushed by a hind foot. Occasional goats have flaky or scabby lesions or laminated crusts on the external ear or even on the poll, back, and pasterns (Littlejohn 1968; Munro and Munro 1980; Heath et al. 1983; Lofstedt et al. 1994), but most have no externally visible lesions. Otoscopic examination (tranquilization advised for adult goats) easily demonstrates the presence of the mite. A plug of yellowish wax is commonly found in the ear canal (Munro and Munro 1980; Cook 1981; Heath et al. 1983), and extracting some of this material with a cotton swab for examination is an alternative means of diagnosis. Palpation of the base of the external ear may elicit a crackling sound associated with exudate in the canal (Nooruddin and Mondal 1996). Rarely, otitis externa progresses to otitis media and interna with head tilt. Body mange caused by Psoroptes resembles sarcoptic mange but is accompanied by less scab formation (Wasfi and Hashim 1986). Before sheep scab due to Psoroptes ovis was eradicated from Texas, Angora goats were noted to have a much more severe form of Psoroptes cuniculi infestation than was seen on dairy goats, as evidenced by serious damage to skin and hair (Graham and Hourrigan 1977). Skin scrapings should be collected from the margin of lesions. If the scrapings are collected into a ziplock bag or petri dish, the sample can be warmed to stimulate movement of the mites during later close examination. Reporting to regulatory authorities may be required.

A separate genus of ear mites of goats is Raillietia (Cook 1981; Lavoipierre and Larsen 1981). The feral goats that harbored only these mites showed no evidence of associated clinical disease, although ear irritation might be expected to occur. Raillietia mites tend to be larger than Psoroptes, and their longer legs originate from the anterior half of the body. The possible involvement of ear mites in transmission of mycoplasma infections is discussed in Chapter 9.

Therapy Treatment of ear mange is often foregone or limited to removal of any bells from goats showing clinical evidence of pruritus (to avoid continual disturbance of the owner). External lesions may be swabbed with an acaricide. Canine ear mite preparations may be used on goats with mites confined to the ear canal, but removal of crusts and debris is necessary and recurrence is likely (Munro and Munro 1980). The life cycle probably takes about three weeks, and several weekly treatments are advised (Littlejohn 1968). In nonlactat-

Demodectic Mange (Demodicosis) Demodex caprae is a cigar-shaped mite that commonly inhabits the hair follicles and sebaceous glands of goats. It has a worldwide distribution. As in other hosts, demodectic mites have been found in the eyelids of goats with no visible lesions anywhere on the body (Himonas et al. 1975). Epidemiology Confinement housing and crowding seem to favor development of demodectic mange. The mites appear to survive only a few hours away from the goats, but infection via contact with contaminated feeders might occur. In fact, natural spread from one adult goat to another has not been documented. The appearance of nodules in certain goats in a herd but not in others may reflect the immune competency of the animal (Das and Misra 1972). This could be related to genetic factors, nutrition (e.g., selenium or protein deficiency), or stress (e.g., high production). It seems likely that goats are first infested as young kids but that lesions do not become detectable until many months later (Williams and Williams 1982). Clinical Signs and Diagnosis Portions of the body exposed to friction, such as the face, neck, shoulders, and sides, are commonly involved, whereas the ventral abdomen and udder remain free of nodules. Where animals with skin lesions have been followed, it has been observed that nodules are first detectable at ten to fifteen months of age (Euzeby et al. 1976). Initially the lesions are very small and only located by careful palpation (Smith 1961). However, defects may be readily detectable in

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(twelve topical treatments) was discontinued (Brügger and Braun 2000). Because secondary bacterial infections are generally absent in undisturbed lesions, antibiotic therapy is not indicated. Treatment is normally only undertaken in show animals, except when nutritional deficiencies exist. It has been suggested that severely affected animals should not be used for breeding because of a possible hereditary susceptibility to the disease (Scott 1988). Free-living Mites

Figure 2.11. Cigar-shaped demodectic mange mites in a smear of exudate expressed from a skin nodule. (Courtesy Dr. M.C. Smith.)

hides at this stage or even earlier (Röhrer 1935). By eighteen to twenty months of age the nodules have enlarged to lentil or pea size, but because they remain painless they may not be noticed unless the goat is clipped (as for a show). Occasional animals demonstrate mild pruritus (Durant 1944), but this is a relatively rare finding. Each nodule corresponds to a distended pilosebaceous follicle. Firm digital pressure will force out a ribbon of yellowish white paste from a central pore. Microscopic examination of this caseous material reveals numerous eggs, larvae, and mature mites (Figure 2.11). The diagnosis is thereby confirmed. The disease process peaks at about three years of age. Nodules may reach a diameter of 0.5 to 1.25 cm. At this time, the severely affected goat may be apathetic and unthrifty, and may lose weight or milk poorly. It is not clear if these signs are because of mange infestation or underlying (nutritional) problems. The nodules become smaller, firmer, and less numerous in older animals. Therapy Various treatments have been proposed. When only a few nodules are present, squeezing or incising each one to permit removal of its contents will result in a cure of the hair follicle thus treated. Iodine or other disinfectant is applied when the nodule is expressed to kill residual mites. Some goats carry several hundred discrete lesions. Others have a generalized dermatitis rather than the typical nodule form of the disease. For them, topical or systemic organophosphates, amitraz (0.025%), or weekly ivermectin or eprinomectin may be effective (Thompson and Mackenzie 1982; Strabel et al. 2003). Because the lesions resolve over weeks or months, documentation of a treatment effect is difficult. Nodules may remain long after the mites have died. In one instance, nodules reappeared after amitraz

Trombiculid mite adults and nymphs are free-living. The larvae (chiggers, harvest mites) are reddish and six-legged. They attack the pasterns, muzzle, and ventrum of animals pastured in infested fields and woods or when contaminated forage is fed to housed animals. Clinical signs of irritation and pruritus, papules, edema, exudation, and ulceration may be expected. Skin scrapings to identify the larvae permit differentiation from other conditions such as chorioptic mange, staphylococcal dermatitis, and zinc deficiency. Mites may be absent in chronic cases. The condition is well reported in sheep (Wall and Shearer 2001) and is occasionally recognized in goats (Nooruddin et al. 1987). An insecticide dip or spray might give eventual relief. Exposure to biting grain or forage mites such as Tyroglyphidae spp. may occasionally cause dermatitis in goats (Matthews 1999). Likewise, a pruritic goat housed with poultry, especially in late summer, might be being attacked at night by poultry mites (Dermanyssus gallinae) (Matthews 1999). Rhabditic Dermatitis and Strongyloidiasis Strongyloides papillosus larvae penetrate unbroken skin, enter capillaries, and travel in the blood to the lungs. Here they exit into air passages and travel up the trachea and down the gastrointestinal tract to the intestines. There are no histologic changes in the skin on first exposure, but pustular dermatitis is created as host resistance develops via repeated exposures. This is characterized by edema, inflammatory infiltration (neutrophils, eosinophils, lymphocytes, and giant cells), and destruction of the larvae. This condition is best described in sheep (Turner et al. 1960). Affected goats are reported to stamp, dance, and nibble at their feet, especially after a rain (Baxendell 1988). Warm, moist habitats for the larvae should be eliminated and the animal treated with an anthelminthic such as fenbendazole, levamisole, or ivermectin. Pelodera (Rhabditis) strongyloides is a free-living soil nematode that can invade portions of skin in contact with moist ground and decaying organic matter (Scott 1988). Although not reported in goats, it could presumably cause pruritic dermatitis in goats housed under unsanitary conditions. Diagnosis is by scraping or skin

46 Goat Medicine

biopsy and control by sanitation, including removal of dirty bedding. The hookworm (Bunostomum) is another nematode that could conceivably produce dermatitis while penetrating the skin. Additional conditions to be considered in the differential diagnosis include contact dermatitis, mange, and trombiculidiasis (chiggers). Parelaphostrongylosis and Elaphostrongylosis Parelaphostrongylus tenuis, the meningeal worm of the white-tail deer, commonly causes neurologic disease in goats in North America. Some paretic and nonparetic goats with P. tenuis infection have developed linear, vertically oriented skin lesions on the neck, shoulder, thorax, or flank (Smith 1981; Scott 1988, 2007). Owners report that the goat has excoriated these areas by biting or rubbing, as if responding to intense pruritus. Lesions are usually unilateral and alopecic, crusted, or scarred (Figure 2.12). One lesion may heal and another appear closer to the goat’s head. One possible explanation is that migrating parasite larvae irritate dorsal nerve roots supplying individual dermatomes. The diagnosis of P. tenuis-induced dermatosis should be entertained when goats with linear pruritic lesions have been exposed to pastures frequented by deer. Neurologic deficits suggesting spinal cord damage and eosinophilia or increased protein in the cerebrospinal fluid lend additional support to the diagnosis. Treatment and control of this parasite are discussed in Chapter 5. Goats in Norway have been affected with a very similar neurologic disease, in which the migrating parasite is Elaphostrongylus rangiferi and the natural host is the reindeer. In one herd pruritus was noted to

precede the neurologic signs (Handeland and Sparboe 1991). When goat kids were experimentally infected with E. rangiferi, pruritus was common from four to ten weeks after infection (Handeland and Skorping 1993). The muscle worm of deer, Elaphostrongylus cervi, has been associated with neurologic disease of goats in Europe, but pruritic skin lesions have not been reported. A differential diagnosis for this syndrome might be psychogenic self-mutilation (Yeruham and Hadani 2003). Examination of biopsy samples reveals only the skin damage induced by chewing or scratching. However, unless the spinal cord is also examined it will not be possible to rule out irritation to a nerve root supplying the affected skin. Filarid Dermatitis Several filarid worms are known to cause dermatitis in small ruminants. Insect vectors, especially flies, deposit larvae in skin wounds. Papular, alopecic, or crusty lesions develop, and are accompanied by pruritus. In Malaysia, a crusty dermatitis of the feet of goats has been ascribed to Stephanofilaria kaeli (Fadzil et al. 1973). In India, Stephanofilaria assamensis has been recovered from skin sores on goats (Patnaik and Roy 1968). Skin scrapings, and smears of blood oozing from the skin after the scrapings have been made, reveal adult parasites and microfilaria. Biopsy samples may be fixed in formalin or macerated and examined with a dissecting scope. Eosinophils predominate in the inflammatory reaction to the parasites. Trichlorfon has been efficacious for treating affected goats. Elaeophora schneideri (a subclinical intra-arterial parasite of mule deer and black-tailed deer in the mountains of the western United States) occasionally infests sheep and elk. Transmission is by horseflies. Adult worms block arteries of the head, and microfilaria lodge in skin capillaries. Erythema, alopecia, ulcers, and crusts appear on the face and poll, and sometimes the abdomen and feet of sheep. Blindness, neurologic signs, and keratoconjunctivitis also may occur. The absence of documented caprine cases may reflect how rarely goats are grazed above 2,000 meters in the mountain ranges. However, the parasite has been reported in the southeastern United States, Texas, and the Pacific coast states, and goats are listed as occasionally infected (Haigh and Hudson 1993). Besnoitiosis

Figure 2.12. Vertically-oriented alopecic lesion on the side of a cashmere goat that had been pastured with white-tail deer, suggesting irritation of a dorsal nerve root by P. tenuis. (Courtesy Dr. M.C. Smith.)

In Africa and the Middle East, protozoal parasites of the genus Besnoitia cause a widespread dermatitis and alopecia in wild and domestic goats. Some workers believe that the organism infecting goats, termed Besnoitia caprae, is distinct from that infecting cattle, B. besnoiti (Njenga et al. 1995). Lesions may be especially severe on the scrotum and lower limbs. The skin is

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thickened to corrugated (hyperkeratosis), sometimes with hyperpigmentation and exudation (Oryan and Sadeghi 1997). Diagnosis is by demonstration in skin biopsy specimens of cysts (oval or spherical, average size 175 × 290 microns) containing bradyzoites and surrounded by a collagen capsule (Bwangamoi 1967; Cheema and Toofanian 1979). There is also a correlation with the presence of Besnoitia cysts in the scleral conjunctiva (Bwangamoi et al. 1989). No specific treatment is available. Control measures for goats have not been described but might include the use of a bovine tissue culture vaccine (Radostits et al. 2007) and avoiding feed contamination with cat feces. Biting flies possibly transmit the parasite.

NUTRITIONAL DISEASES A goat subject to deficiencies in dietary energy or protein can be expected to have a dry, sparse hair coat and dry, thin, scaly skin. These changes are nonspecific because they occur with many chronic, wasting diseases. Copper deficiency, which is discussed in Chapter 19, has been associated with depigmentation of the hair coat (Lazzaro 2007). Certain trace mineral or vitamin deficiencies cause changes in the skin that have been described in more detail. Alopecia, possibly related to liver damage, has been produced by experimental feeding of Aristolochia bracteata in goats in Sudan (Barakat et al. 1983). Zinc Deficiency and Zinc Responsive Dermatosis It has been suggested that a practical level of dietary zinc in production diets is 45 to 75 ppm (McDowell et al. 1991). The National Research Council (2007) now admits that a previous recommendation of 10 ppm did not allow for poor absorbability, which can be estimated to be as low as 15%. Etiology Calcium excesses in the diet may contribute to a relative zinc deficiency. This might explain zincresponsive dermatitis in nonlactating does or male goats receiving dairy rations or alfalfa. Zinc deficiency was recognized in two aged nonlactating does after their diet was switched to an alfalfa gruel to compensate for tooth loss (Singer et al. 2000). Other minerals which influence zinc absorption are selenium, copper, and cadmium (National Research Council 2007). Zinc is not stored in the body in an available form, so a daily dietary source is needed. Some animals appear to have inadequate absorptive abilities (possibly genetically determined, KrametterFroetscher et al. 2005), because dermatosis persists in the face of normal dietary concentrations of zinc and interfering minerals. Second-generation goats on an experimental nickeldeficient diet developed zinc deficiency and associated

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parakeratotic skin changes (Anke et al. 1977). This is unlikely to occur with ordinary diets. Clinical Signs Clinical signs observed in goats with zinc deficiency include hyperemia and pruritus (inconstant) of the skin; alopecia; thick fissured crusts on the back legs, escutcheon, face, and ears; and dandruff-like scales over the rest of the body (Neathery et al. 1973; Nelson et al. 1984; Scott 1988; Krametter-Froetscher et al. 2005). Crusts commonly encircle the nares, eyes, and mouth. The hair of zinc-deficient goats has been described as greasy and matted (Groppel and Hennig 1971). Fiber break with loss of mohair can have serious economic consequences in Angoras (Schulze and Üstdal 1975). Weight loss may occur; clinical aspects of zinc deficiency unrelated to the skin are discussed further in Chapter 19. Diagnosis and Treatment Skin biopsies are important for demonstration of hyperkeratosis and parakeratosis and for ruling out other conditions with similar signs (e.g., mange, dermatophilosis). The diagnosis of zinc deficiency by laboratory tests is difficult. It appears that some goats may have a zinc responsive dermatitis, although plasma, liver, and even dietary zinc levels appear to be within normal ranges (Reuter et al. 1987). Serum levels less than 0.8 ppm might be associated with skin lesions. Lower serum zinc concentrations (0.54 ppm) have been recorded in goats from Florida herds with a history of seasonal dermatosis when compared with serum levels in other herds without such history (0.83 ppm) (McDowell et al. 1991). An Austrian report gives the normal caprine serum zinc range as 0.57 to 0.63 ppm (Krametter-Froetscher et al. 2005). In many instances, the diagnosis is achieved by response to treatment. A rather arbitrary dose of 1 gram zinc sulfate orally per day has been used with good success; if marked improvement has not occurred after two weeks of therapy, other diagnoses should be pursued more vigorously. There is a published report of a single goat with skin lesions of lateral truncal alopecia and scaling improving in seven to ten days with institution of 14 grams zinc sulfate orally per day for six weeks. Signs reappeared two to three weeks after cessation of therapy (McDowell et al. 1991). In the Austrian report, two adult goats with onset of clinical signs during pregnancy responded to 1 gram zinc sulfate per day, whereas the response to 50 to 200 mg zinc oxide per day was less complete (KrametterFroetscher et al. 2005). The efficacy of dietary zinc methionine for alleviating signs in goats has not been documented. A mineral supplement that includes zinc should be offered routinely, with additional zinc for animals with a suspected hereditary basis for the

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dermatosis. A slow-release bolus containing zinc, cobalt, and selenium is available in the United Kingdom (Matthews 1999). Dietary excesses of calcium should be corrected.

tations of deficiency are discussed in Chapter 5 and ocular manifestations in Chapter 6.

Iodine Deficiency

Because beta-carotene, which is abundant in greenleaved plants, is converted into vitamin A after ingestion, deficiencies are unlikely when goats are fed good pasture or green hay. Grains (except yellow corn and green peas), roots (except carrots and sweet potatoes), and old or weathered hays are low in carotene. Cases of vitamin A deficiency in goats are most likely to occur in semi-arid environments (during the dry season or periods of drought) or when the diet consists of poor, old hay and grain other than corn. Experimental aflatoxicosis in goats has caused a gradual decrease in serum vitamin A levels (Maryamma and Sivadas 1973). Colostrum is rich in vitamin A and usually supplies the needs of the kid until forage consumption begins. Colostrum-deprived kids can be expected to be deficient in vitamin A.

Diseases of the thyroid gland are discussed in detail in Chapter 3, and the role of iodine in caprine nutrition is discussed in Chapter 19. Etiology Certain soils (such as that found in much of the northern United States and the Himalayas) are deficient in iodine. Goitrogens (such as members of the Cruciferae family, see Chapter 3) may interfere with uptake of iodine by the thyroid gland. Additionally, inherited abnormalities of thyroid function have been recognized in inbred Dutch goats. Clinical Signs Adult goats with goiter caused by iodine deficiency generally show no skin changes (Kalkus 1920; Dutt and Kehar 1959). Likewise, clinical signs of hair loss or skin abnormalities were absent in one outbreak of goiter and cretinism in Angora kids ascribed to consumption of goitrogens during pregnancy (Bath et al. 1979). In iodine deficiency severe enough to cause stillbirth, however, newborn kids sometimes had a normal hair coat but often were hairless or covered with very fine hair (Kalkus 1920). Skin lesions have been reported in experimental hypothyroidism produced by administration of thiourea to kids. A rough hair coat and subcutaneous edema were noted clinically. Histologic changes included hyperkeratosis and plugging of hair follicles (Sreekumaran and Rajan 1977). Kids with hereditary goiters were similar to thiourea-treated animals in that they were sluggish and grew poorly. Again, the hair coat was sparse and the skin thick and scaly (Rijnberk 1977). It appears that goats with goiter may or may not have accompanying skin lesions, but that iodine deficiency should not be suspected as the cause of skin disease in the absence of goiters. Treatment and Prevention Iodine deficiency can usually be prevented by supplying an iodized salt or salt and mineral product (as the only source of supplemental salt). Excessive feeding of goitrogens should be avoided. Weekly application of an iodine-containing solution (such as 1 ml of tincture of iodine) to the skin will also meet the needs of the animal (Kalkus 1920). Vitamin A Deficiency Vitamin A is necessary for normal function of epithelial tissues, including the skin. Neurologic manifes-

Etiology

Clinical Signs and Diagnosis Clinical signs relative to the skin include a rough, dry hair coat, patchy alopecia, and a generally unhealthy appearance (Majumdar and Gupta 1960; Caldas 1961; Dutt and Majumdar 1969). Hyperkeratosis (identified histologically) (Scott 1988) and plasma vitamin A levels less than 13 μg/dl, at least in sheep (Ghanem and Farid 1982), support the diagnosis, as do low levels of vitamin A in the liver (except for precolostral neonates). Treatment and Prevention Dietary supplementation, as discussed in the nutrition chapter, is preferable to injectable vitamin A. An excellent source is leafy alfalfa or alfalfa meal. Intramuscular or subcutaneous injection of vitamin A (3,000 to 6,000 IU/kg every two months) is appropriate for individual unthrifty goats or when daily oral supplementation is not possible. A single oral dose of 600,000 IU has proven effective in lambs for thirty-four weeks, and it is recommended that this be given two months after the start of the dry season (Ghanem and Farid 1982). Massive overdose of vitamin A, as has been achieved in experimental feeding trials, results in a moderate hyperplasia of the dermis and seborrhea of the ventral abdominal and inguinal skin (Frier et al. 1974). Vitamin E and Selenium Responsive Dermatosis A nonpruritic dermatosis characterized by a dry, thin hair coat, general seborrhea and scales, and periorbital alopecia has been observed in kids and adult goats (Smith 1981).

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In some instances, dietary selenium deficiency has been documented, and the response to injectable vitamin E/selenium has been dramatic. In other goats, diagnosis was based on negative skin scrapings and response to both injectable E/selenium and oral vitamin E (400 IU) given with vegetable oil daily for one month. Dietary supplementation with black oil sunflower seeds or wheat germ oil might be helpful because of vitamin E and fat content (Konnersman 2005b). Controlled therapeutic trials have not been conducted, and criteria for positively diagnosing the condition have not been established. Zinc deficiency is an important differential. Skin biopsy results of goats with vitamin E and selenium responsive dermatosis have revealed orthokeratotic hyperkeratosis, whereas zinc responsive disease is characterized by parakeratotic hyperkeratosis (Scott 1988). Selenium Toxicity Hair loss in goats consuming Astragalus spp., especially involving the beard and flank region, has been linked to possible selenium excess (Reko 1928). This seems plausible because selenium toxicity from a variety of selenium-concentrating plants or from contaminated water causes loss of mane and tail hairs in horses. In another herd outbreak ascribed to consumption of a seleniferous (500 ppm) Astragalus spp., the only reported skin change in goats that died was a rough hair coat (Hosseinion et al. 1972). Selenium may substitute for sulfur in sulfur-containing amino acids in the hair and hoof (Scott 1988). This leads to alopecia and lameness, with cracks and deformities developing in horns and hooves (Gupta et al. 1982), as discussed in Chapter 4. Sulfur Deficiency A recently recognized condition of severe fleece eating in cashmere-producing goats and of sheep in one valley (Haizi area) in China has been ascribed to sulfur deficiency, possibly compounded by calcium and copper deficiency. Affected goats repeatedly bite bits of fleece off themselves or other animals in the flock, concentrating on the fiber over the hips, abdomen, and shoulder. Some animals are left with almost naked skin and may die of exposure. Skin is keratinized and hair follicles are reduced in size and number. Signs are alleviated by moving to another valley or by the arrival of lush spring grass. The sulfur content of the fiber in affected animals was low (2.4%) compared with a normal content of 4%. Medicated pellets containing aluminum sulfate prevented or treated the skin condition, although muscle atrophy and kidney lesions were not reversed (Youde 2001, 2002; Youde and Huaitao 2001).

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Rule-outs for such a herd problem include external parasites, lack of dietary fiber, boredom, and accidental deposition of concentrates into the fleece during distribution of feed.

ENVIRONMENTAL INSULTS The skin may be damaged by excessive exposure to light, cold, or irritants such as urine. Bites by poisonous snakes and spiders undoubtedly affect goats occasionally but are poorly documented. Sunburn Exposure to sunlight is associated with the development of skin tumors in white goats, as discussed below. Light-skinned animals exposed to bright sunlight (ultraviolet light, 290 to 320 nm) (Scott 1988) after a winter stabling period are also susceptible to sunburn, especially of the muzzle, perineum, and teats. Signs include erythema, edema, vesicles, ulceration, and crusts (Scott 2007). Prevention involves gradually increasing times of exposure to sunlight and applying sunblocking ointments or iodine teat dips after milking. Treatment is by temporary removal from the sun and use of soothing burn ointments. Contamination of milk should be avoided. Photosensitization In photosensitization, superficial layers of lightly pigmented skin are sensitized to ultraviolet light (320 to 400 nm) of wavelengths longer than those causing simple sunburn. Etiology There are several mechanisms by which a photodynamic agent may reach the skin and cause dermatitis if exposed to light (Galitzer and Oehme 1978). Certain toxins are ingested preformed, and are said to cause primary photosensitization. Examples include phenothiazine, fagopyrin (from buckwheat, Fagopyrum esculentum), hypericin (Bale 1978) (from Hypericum spp.) and furocoumarins (from Ammi majus and Thamnosma texana) (Ivie 1978; Scott 1988, 2007). Secondary, or hepatogenous, photosensitization occurs when the normal end product of chlorophyll degradation in the rumen, phylloerythrin, accumulates because of faulty liver excretion. Any severe liver disease could conceivably lead to photosensitization in goats consuming chlorophyll and exposed to sunlight, but toxic plants are most frequently incriminated. These include Lantana (Pass 1986), Agave lecheguilla (Mathews 1938; Burrows and Stair 1990), Nolina texana (Mathews 1940), Panicum coloratum (Muchiri et al. 1980), Tribulus terrestris possibly in association with the saprophytic fungus Pithomyces chartarum (Glastonbury and Boal 1985; Jacob and Peet 1987), and Panicum coloratum (Muchiri et al. 1980). Additional hepatotoxic plants are listed in

50 Goat Medicine

Chapter 11. An inherited congenital porphyria has been reported in other species, but apparently not in goats.

until one month after parturition will prevent the condition (Kellerman et al. 2005).

Clinical Signs

Special attention should be given to drying of the ears when kids are born in cold environments. Otherwise it is common for the ear tips to develop frostbite. If the initial edematous stage is not treated, the affected skin becomes necrotic and eventually sloughs. The ear tips are rounded and alopecic and the remaining pinna is of variable length. The feet of neonates and teats and scrotum of adults are also at risk of frostbite under extreme environmental conditions. Ensuring that the extremities remain dry is important for prevention of such injuries. Immediate first aid involves rapid thawing in warm water 106° to 111°F (41°C to 44°C) (Scott 1988) or with a hair dryer. Beef calf producers report that freezing of the ear tips can be prevented by using stockinette or duct tape to keep the ears closely apposed to the warmer head during the first days.

The clinical signs in goats with photosensitization vary, depending on the protection afforded the skin by long hair or pigmentation and whether liver disease is present. The head, udder, and vulva of white breeds exposed to sunlight initially develop erythema, edema, and intense pruritus. Photophobia is observed and the goats seek shade. Acutely there may be dyspnea or dysphagia. Eventually necrosis and sloughing of lips or teats may occur. Pigmented skin is unaffected. The entire dorsum may be involved in recently shorn animals. Liver function tests help to differentiate primary from secondary photosensitization. Exudation of yellow, serous fluid from the skin surface and intense icterus of the entire carcass are reported in goats with hepatogenous photosensitization from Tribulus terrestris. This condition is called geeldikkop, which means “yellow thick head.” Similar lesions have been produced experimentally by oral dosing of goats with sporidesmin. Feral and Angora cross goats were more resistant than Saanens, which in turn required two to four times as much sporidesmin as sheep to produce comparable liver lesions and clinical signs (Smith and Embling 1991). Therapy and Prevention Affected goats should be removed from the sun, and additional ingestion of hepatotoxic plants or toxins avoided. This may require moving or supplementing range animals. Laxatives might be helpful if ingestion has occurred recently, and antihistamines and antibiotics are given if much skin is destroyed. Affected skin is sprayed with methylene blue and fly repellents if housing is not possible. Selection for skin pigmentation will decrease the prevalence of photosensitization, but losses resulting from liver disease will continue unabated unless exposure to hepatotoxins is prevented. Kaalsiekte The South African bitterkarroo bush Chrysocoma ciliata (C. tenuifolia) produces skin disease in young kids and lambs if their dams consume large quantities of the plant pre partum. The toxin is excreted in milk, causing hair shedding and diarrhea (Steyn 1934). Kids develop pruritus when exposed to sunlight and lick off large patches of hair. Sequelae include death from exposure, a crusty dermatitis from sunburn, and abomasal hairballs. Supportive treatment (protection from sunburn and wind, laxatives to remove hairballs) should continue until hair returns. Keeping the does and ewes off the infested veld from one month before

Frostbite

Ergotism Ergot toxicity (a mycotoxicosis caused by alkaloids produced by Claviceps purpurea) causes sloughing of the extremities in cattle, similar to frostbite, and is potentiated by exposure to cold. There is a single report of lameness and gangrenous necrosis with sloughing just above the coronary band in goat kids grazing on fescue parasitized by the fungus (Hibbs and Wolf 1982). Urine Scald During the breeding season bucks urinate on their face, beard, and front legs whenever sexually aroused. Although this habit heightens the doe-attracting aroma of the breeding male, it can lead to dermatitis in the areas that are continuously wet with urine. Clipping of long hair allows for faster drying of the skin. Skin lesions can be washed with a mild soap or vinegar solution (5 ml in 500 ml water, Konnersman 2005a) and then liberally coated with petroleum jelly, zinc oxide, or other water repellent ointment daily, until the end of the breeding season. Similar skin care year-round may be required for intersexes or males after urethrostomy or bladder marsupialization if the perineum or inside of the thighs becomes wet during urination. Males on a high protein diet may develop posthitis and moist infections of the skin of the prepuce. In addition to general wound care, the ration should be corrected, as described in Chapters 12 and 19. Other Contact Dermatitis Conditions Caustic agents that cause stomatitis (see Chapter 10) may be expected to cause dermatitis as well, if applied

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to the external skin. There are various anecdotal reports of occasional skin irritation and hair loss following topical application of numerous parasiticides. If this occurs, the animal should be washed with warm water and a mild detergent to remove residual product. Dehorning Paste An alkaline paste is sometimes used by producers to disbud young kids. The paste eats through and destroys the skin from which horns would grow. Clipping hair and applying a ring of petroleum jelly may help contain the paste to the horn bud. Rubbing against other animals and pawing with a hind foot in response to local pain spread the paste and cause skin necrosis elsewhere on the body of the disbudded kid or other pen mates. Paste dehorning should be discouraged. Milk Some kids develop alopecia or even raw skin lesions (due to rubbing) on the lips and face where contact with milk or milk replacer has occurred. The condition has been termed “labial dermatitis” and can be prevented by washing or wiping the kid’s face after each feeding (King 1984). Decubital Sores Emaciated or recumbent animals commonly develop full thickness skin necrosis over bony prominences such as elbows, hocks, and sternum. Deep, clean, dry bedding and frequent turning of the animal help prevent such lesions. Even with daily cleansing and drying of the sores, healing occurs very slowly, and only if underlying debilitating conditions are corrected. Sternal abscesses are discussed in Chapter 3. Plant Awn Migration The barbed seeds of numerous plants, especially grass awns, can penetrate the skin and migrate in the subcutaneous or deeper tissues. Nodules, abscesses, or draining tracts may develop (Scott 2007). An extensive discussion of potentially damaging plants in southern Africa (Kellerman et al. 2005) does not mention goats, but there is no reason to believe that they would not be affected.

NEOPLASIA The most common skin tumors of the goat are cutaneous papilloma (warts), squamous cell carcinoma, and melanoma. Hemangioma, hemangiosarcoma, histiocytoma, mast cell tumor, and cutaneous lymphosarcoma have also been reported (Bastianello 1983; Manning et al. 1985; Roth and Perdrizet 1985; Allison and Fritz 2001; Bildfell et al. 2002; Konnersman 2005b). Ectopic mammary gland, which could be mistaken for a neoplastic condition, is discussed in Chapter 3.

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Papilloma Common warts probably occur much more frequently in goats than the caprine literature suggests. This is because those on the head or neck are benign and often self-limiting. If noticed at all, they are recognized as warts and because of a favorable prognosis, biopsy or treatment is not attempted. Favorable response to autogenous vaccine, after surgical removal of the largest warts, has been reported in a study with no untreated controls (Rajguru et al. 1988). The involvement of multiple animals in one closely confined herd has been taken as evidence for an infectious origin (Davis and Kemper 1936), although a wart virus has not been demonstrated in caprine papillomas. Udder Warts Warts on the udder have a different clinical course and are apparently limited to white goats (Saanens or Angoras) that have lactated at least once (Moulton 1954; Ficken et al. 1983; Theilen et al. 1985). The papillomas involve the white skin of both udder and teats and are typically multiple (Figure 14.5). They may either be flaky or form elongated cutaneous horns. Some transform into squamous cell carcinomas with wide base and ulcerated surface. The carcinomas may rarely metastasize to the supramammary lymph node. Additional discussion of these tumors is included in Chapter 14. Carcinomas Carcinomas of the skin also occur on other regions of the goat and without a preceding papilloma lesion. Again, white breeds in sunny climates are at risk. Angoras and Boer goats frequently develop carcinomas of the perineum (vulva and anus) (Thomas 1929; Curasson 1933; Hofmeyr et al. 1965; Yeruham et al. 1993). Ears, horn stumps, and muzzle (van der Heide 1963) may also be involved. The tumor may be sessile or pedunculated and becomes ulcerated as it enlarges. Detection often follows development of a foul-smelling exudate (Ramadan 1975). Possible origins for these tumors include squamous cells, basal cells, and sebaceous glands. Early surgical treatment is curative; otherwise affected animals should be culled. An affected ear can be easily amputated using local anesthesia and a Burdizzo emasculatome, placed on an angle to give a more cosmetically acceptable pointed shape to the remaining ear cartilage. Myiasis hastens the death of animals left untreated. Melanomas Melanomas appear to involve the same skin areas as the carcinomas, especially the vulva, perineum, and ear (Venkatesan et al. 1979; Bastianello 1983; Ramadan 1988). Indeed, it is sometimes unclear whether a given

52 Goat Medicine

tumor is a pigmented basal cell carcinoma or a melanoma (Jackson 1936). In other instances, both clinical course (metastases to internal organs) and histologic findings are consistent with malignant melanoma (Sockett et al. 1984). The prognosis is poor, as metastases commonly occur to local nodes, liver, and lung. A breed predilection was demonstrated in the Sudan in a review of sixty-two affected goats; the gray or brown “American” goats originally imported from Syria were more commonly affected than the more numerous all black native Nubian goats (Ramadan 1988). The Angora goat has been proposed as a model for human melanomas, because both tumors and benign melanocytic lesions can be induced by exposure to sunlight (Green et al. 1996).

INHERITED OR CONGENITAL CONDITIONS A possibly inherited absence of hair at birth has been reported in a buck kid and his sire (breed unspecified) (Kislovsky 1937). The sire developed a nearly normal fleece as it grew older, but the kid died young. Neither histology nor additional matings were performed. “Sticky kid syndrome” is a congenital disease reported in purebred Golden Guernsey goats, and may be inherited as a recessive character. At birth the kids have a sticky and matted coat that does not dry normally. The coat remains harsh and sticky in older goats (Jackson 1986). Kids, unlike lambs, do not appear to develop congenital changes in the hair coat when exposed in utero to border disease virus (Orr and Barlow 1978). Wattle cysts, which are located subcutaneously in the cervical region, are discussed in Chapter 3.

MISCELLANEOUS CONDITIONS Dermatologists in referral hospitals see a disproportionate number of goats with “uncommon” skin diseases that have not responded to empirical treatments, including antibiotics, parasiticides, and manipulations of the diet. Extensive diagnostic work-up has characterized and identified the cause of some of these conditions, but others remain perplexing. In particular, crusting lesions of Nubian goats, especially involving the ears and face, have frequently defied attempts to identify an etiology or an effective treatment. Pemphigus Pemphigus foliaceus is an autoimmune disease in which the affected individual (man, dog, cat, horse, or goat) develops auto-antibodies against the glycocalyx of keratinocytes. Reports of the condition in goats are few (Jackson et al. 1984; Scott et al. 1984; Valdez et al. 1995; Pappalardo et al. 2002). There is no evidence that the condition is hereditary.

Clinical Signs and Diagnosis Clinical findings include vesicles or blisters, pustules, crusts, alopecia, and sometimes pruritus. The lesions may be generalized over the entire body or may be concentrated in or begin in a more restricted location, such as the perineal region, ventral abdomen, and groin (Jackson et al. 1984). Diagnosis requires fullthickness skin biopsies of lesions containing intact vesicles or pustules. Routine histology (formalin fixation) reveals intraepidermal acantholysis with formation of clefts, vesicles, or pustules. Cells of the stratum granulosum may be seen attached to the overlying stratum corneum (Scott 1988). These granular “clingons” may also be found in direct smears of intact vesicles, along with nondegenerate neutrophils and/or eosinophils (Scott 2007). Direct immunofluorescence testing (tissue in Michel’s fixative; no glucocorticoids administered in the past three weeks) reveals intercellular deposition of immunoglobulin. Serologic testing (indirect immunofluorescence) is unreliable for the diagnosis of caprine pemphigus (Scott et al. 1987). Treatment Treatment of pemphigus may be attempted with high doses of systemic glucocorticoids (1 mg/kg prednisone or prednisolone IM twice daily for seven to ten days, then alternate morning therapy at reduced dosage). A long-acting corticosteroid injection (dexamethasone-21-isonicotinate 0.04 mg/kg IM) once every two months suppressed clinical signs in one goat (Pappalardo et al. 2002) but the potential risks are greater. Oral prednisolone is not used because of very low bioavailability in ruminants (Koritz 1982). In young or nonresponsive goats, chrysotherapy with aurothioglucose (1 mg/kg weekly until response is observed, then monthly) may be tried. This drug has been discontinued in the United States. Although adverse reactions to gold have not been reported in goats, hemograms and urinalyses should be monitored. Gold treatment was successful in one reported case (Scott et al. 1984) and unsuccessful in another (Valdez et al. 1995). Alopecic Exfoliative Dermatitis, Psoriasiform Dermatitis A nonpruritic, seborrheic skin condition affecting pygmy goats of all ages has been described in England. Hair loss, scaling, and crusting occur around the eyes, lips, chin, ears, ventrum, and perineum. Histology reveals a psoriasiform dermatitis, and the condition responds to steroids but recurs when treatment is stopped (Jefferies et al. 1987, 1991). There is orthokeratotic and parakeratotic hyperkeratosis (Scott 2007). A very similar condition has been studied in pygmy goats in the Netherlands (Kuiper 1989). The condition was not contagious and did not respond to administra-

2/Skin

tion of corticosteroids, zinc, vitamin A, or selenium. A hereditary basis was suspected. Lichenoid Dermatitis This idiopathic condition was reported in a twoyear-old Boer buck in Israel (Yeruham et al. 2002). Pruritic flat-topped angular scaly papules were present in the skin over the entire surface of the goat. The lesions were 10 to 20 mm in diameter but coalesced into plaques on the head. Some lesions were fissured. Histologic findings included orthokeratotic hyperkeratosis, epidermal hyperplasia, and microabscesses. Poxviruses, dermatophytes, and granulomatous and neoplastic conditions were ruled out by histopathology. A photograph of a similar case from Belgium, which resolved spontaneously after several months, has been published by Scott (2007). Allergy or Hypersensitivity Occasionally a pruritic, alopecic to crusty condition is seen on the dorsal midline of pastured goats in spring and summer. No external parasites are found on the animal, and practitioners have implicated a hypersensitivity to the saliva of Culicoides spp. midges (Scott 2007). Stabling at dusk and dawn may limit exposure to the insects and a brief course of systemic corticosteroids may alleviate the pruritus. Other cases of poorly explained pruritic skin disease have been observed and defied diagnostic efforts to determine the etiology. In one such instance, orthokeratotic hyperkeratosis and perivascular infiltration with eosinophils in a five-year-old wether with crusting on the back and neck suggested allergy, as did response to dexamethasone therapy, but skin testing and manipulation of diet and environment were unsuccessful (Humann-Ziehank et al. 2001).

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Tarlatzis, C.B.: Un cas de rage prurigineuse chez la chèvre. Annales Méd. Vét. 98:87–89, 1954. Tassi, P., Puccini, V., and Giangaspero, A.: Efficacy of ivermectin against goat warbles (Przhevalskiana silenus Brauer). Vet. Rec. 120:421, 1987. Theilen, G., et al.: Goat papillomatosis. Am. J. Vet. Res. 46:2519–2525, 1985. Thomas, A.D.: Skin cancer of the Angora goat in South Africa. 15th Annual Report of the Director of Vet. Services, Dept. of Agric., South Africa, pp. 661–761, 1929. Thompson, J.R., and Mackenzie, C.P.: Demodectic mange in goats. Vet. Rec. 111:185, 1982. Tiddy, R., and Hemi, D.: A scabby mouth-like condition in Saanen goat kids. N. Z. Vet. J. 34:119, 1986. Turner, J.H., Shalkop, W.T., and Wilson, G.I.: Experimental strongyloidiasis in sheep and goats. IV. Migration of Strongyloides papillosus in lambs and accompanying pathologic changes following percutaneous infection. Am. J. Vet. Res. 21:536–546, 1960. Uzal, F.A., et al.: Malassezia slooffiae-associated dermatitis in a goat. Vet. Dermatol., 18:348–352, 2007. Valdez, R.A., et al.: Use of corticosteroids and aurothioglucose in a pygmy goat with pemphigus foliaceus. J. Am. Vet. Med. Assoc., 207:761–765, 1995. Valle, J., et al.: Staphylococci isolated from healthy goats. J. Vet. Med. B, 38:81–89, 1991. van Dam, R.H., Boot, R., van der Donk, J.A., and Goudswaard, J.: Skin grafting and graft rejection in goats. Am. J. Vet. Res. 39:1359–1362, 1978. van der Heide, L.: Some cases of cutaneous carcinoma in goat and cow on Curaçao. Tijdschr. Diergeneesk., 88:510–512, 1963. van der Westhuysen, J.M., Wentzel, D., and Grobler, M.C.: Angora Goats and Mohair in South Africa. 3rd Ed. Port Elizabeth, South Africa, NMB Printers, 1988. Van Lancker, S., Van den Broeck, W., and Simoens, P.: Morphology of caprine skin glands involved in buck odour production. Vet. J., 170:351–358, 2005. Van Tonder, E.M.: Notes on some disease problems in Angora goats in South Africa. Vet. Med. Rev. 1/2:109–138, 1975. Venkatesan, R.A., Nandy, S.C., and Santappa, M.: A note on the incidence of melanoma on goat skin. Indian J. Anim. Sci. 49:154–156, 1979. Waldvogel, A., et al.: Caprine herpesvirus infection in Switzerland: some aspects of its pathogenicity. Zbl. Vet. Med. B 28:612–623, 1981. Wall, R., and Shearer, D.: Veterinary Ectoparasites: Biology, Pathology and Control. 2nd Ed. Oxford, Blackwell Science Ltd, 2001. Wasfi, I.A., and Hashim, N.H.: Ivermectin treatment of sarcoptic and psoroptic mange in sheep and goats. World Anim. Rev. 59:29–33, 1986. Watson, P.: Differential diagnosis of oral lesions and FMD in sheep. In Pract., 26:182–191, 2004. Wentzel, D., and Vosloos, L.P.: Pre-natale ontwikkeling van follikelgroepe by die Angorabok. (Prenatal development of follicle groups in the Angora goat hair.) Agroanimalia 6:13–20, 1974. Williams, J.F., and Williams, C.S.F.: Psoroptic ear mites in dairy goats. J. Am. Vet. Med. Assoc. 173:1582–1583, 1978.

60 Goat Medicine Williams, J.F., and Williams, C.S.F.: Demodicosis in dairygoats. J. Am. Vet. Med. Assoc. 180:168–169, 1982. Whitney, J.C., Scott, G.R., and Hill, D.H.: Preliminary observations on a stomatitis and enteritis of goats in southern Nigeria. Bull. Epiz. Dis. Af. 15:31–41, 1967. Wooldridge, M.J.A., and Wood, J.: Some aspects of scrapie epidemiology in the goat. Goat Vet. Soc. J. 12(2):4–7, 1991. Wright, F.C., Guillot, F.S., and George, J.E.: Efficacy of acaricides against chorioptic mange of goats. Am. J. Vet. Res. 49:903–904, 1988. Yadav, A., Khajuria, J.K., and Soodan, J.S.: Efficacy of ivermectin against warble fly larvae in goat. Indian Vet. J., 2006; 83:1133–1134, 2006. Yeruham I., Elad, D., and Perl, S.: Dermatophilosis in goat in the Judean foothills. Rev. Med. Vet., 154:785–788, 2003. Yeruham, I., and Hadani, A.: Self-destructive behaviour in ruminants. Vet. Rec., 152:304–305, 2003. Yeruham, I., Rosen, S., and Perl, S.: An apparent flea-allergy dermatitis in kids and lambs. J. Vet. Med. A, 44:391–397, 1997. Yeruham, I., et al.: Dermatophilosis (Dermatophilus congolensis) accompanied by contagious ecthyma (orf) in a flock of Yaez in Israel. Isr. J. Vet. Med. 46:74–78, 1991. Yeruham, I., et al.: Perianal squamous cell carcinoma in goats. J. Vet. Med. A, 40:432–436, 1993.

Yeruham, I., et al.: Apparent idiopathic interface disease in a Boer billy goat. J. S. Afr. Vet. Assoc., 73:77–78, 2002. Youde, H.: Preliminary epidemiological and clinical observations on shimaor zheng (fleece-eating) in goats and sheep. Vet. Res. Commun., 25:585–590, 2001. Youde, H., and Huaitao, C.: Studies on the pathogenesis of shimao zheng (fleece-eating) in sheep and goats. Vet. Res. Commun., 25:631–640, 2001. Youde, H.: An experimental study of the treatment and prevention of shimao zheng (fleece-eating) in sheep and goats in the Haizi area of Akesai county in China. Vet. Res. Commun., 26:39–48, 2002. Zahler, M., et al.: Genetic evidence suggests that Psoroptes isolates of different phenotpes, hosts and geographic origins are conspecific. Int. J. Parasitol., 28:1713–1719, 1998. Zahler, M., et al.: Molecular analyses suggest monospecificity of the genus Sarcoptes (Acari: Sarcoptidae). Int. J. Parasitol., 29:759–766, 1999. Zamri-Saad, M., Hizat, A.K., and Kamil, W.M.: Effect of ivermectin on sarcoptic mange lesions of goats. Trop. Anim. Health Prod., 22:144–145, 1990. Zenner, L., Drevon-Gaillot, E., and Callait-Cardinal, M.P.: Evaluation of four manual tick-removal devices for dogs and cats. Vet. Rec., 159:526–529, 2006.

3 Subcutaneous Swellings Swellings With Unrestricted Distribution 61 Hematoma and Seroma 61 Cellulitis and Abscess 62 Emphysema 62 Edema 62 Lymph Node Enlargement 62 Caseous Lymphadenitis 62 Melioidosis 67 Other Infectious Agents 67 Lymphosarcoma 68 Prominent Lymph Nodes of Normal Size 68 Swellings Involving the Head 68 Retention of a Cud in the Cheek 68 Salivary Mucocele 69 Abscess 69 Osteodystrophia Fibrosa 71 Bottle Jaw 71 Swelled Head of Bucks 71 Deformation of the Cranium 71

Whether the owners in a locality refer to them as lumps, bumps, bunches, or something else, swellings beneath the skin on a short-haired goat are likely to attract attention and require diagnosis, if not a treatment. The diagnosis depends on both the physical characteristics of the lump and its exact anatomic location. Aspiration, along with culture or cytologic examination dictated by the nature of the aspirate, can usually provide a definitive diagnosis. However, after the practitioner gains experience with goats, aspiration is only occasionally required. Herd history, signalment of the animal, and physical examination findings give reasonable certainty in the diagnosis of numerous benign conditions. Aspiration, then, is limited to confirmation of diagnoses that might require some other action, often surgery, or that carry a grave prognosis.

SWELLINGS WITH UNRESTRICTED DISTRIBUTION Certain conditions can cause local swelling over almost any part of the goat’s body. They will be considered before conditions with a more regional distribution. Masses limited to the dermis or epidermis, Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Swellings Involving the Neck and Chest 72 Abscesses Other Than Caseous Lymphadenitis 72 Tissue Necrosis (“Sterile Abscesses”) Caused by Injections 72 Wattle Cyst and Thyroglossal Duct Cyst 72 Thyroid Gland and Goiter 72 Thymus 76 Phlebitis 77 Atlantal Bursitis 77 Sternal Abscesses and Hygromas 77 Warbles 77 Tapeworm Cysts 77 Swellings Involving the Abdomen and Escutcheon 78 Umbilical Hernia 78 Umbilical Abscess 78 Abdominal or Flank Hernia 78 Ventral Hernia 78 Ventral Edema of Angoras 78 Urethral Rupture 79 Gangrenous Mastitis 79 Ectopic Mammary Gland 79 References 79

joint distension, and changes involving the mammary gland and scrotum are discussed in other chapters. Hematoma and Seroma A fresh hematoma is easily diagnosed by aspiration of nonodorous, sterile, red fluid. A yellow sterile fluid containing few erythrocytes is present in a seroma or organized hematoma. Diagnostic aspiration, however, is not without risk. Even with very careful attention to skin preparation, the needle is likely to carry a few bacteria into the accumulated fluid. Unless the hole in the skin is offset from the point where the needle enters, a small tract will permit leakage of fluid and retrograde entry of more bacteria. It is hard to imagine better growing conditions for a bacterial culture than in whole blood or serum at body temperature. The practitioner might choose to drain a fluctuating lump, whether it be hematoma, seroma, or abscess. This procedure should be delayed a week or more if a hematoma is suspected to avoid renewed bleeding when the pressure of containment is relieved. If the swelling is not over a large blood vessel and antibiotic residues in milk or meat are of no concern, then small 61

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fluid pockets may be drained through a needle and subsequently injected with penicillin or other antibiotic. A pressure bandage may prevent recurrence. Larger pockets must be opened widely and packed with gauze soaked in an antiseptic or provided with indwelling drains if proper healing is to occur. Seromas on the poll of breeding bucks, resulting from regular head bashing with other males, are best left totally alone. Cellulitis and Abscess Cellulitis is an acute, diffuse, edematous, suppurative inflammation of deep subcutaneous tissues or muscle. The swelling may be painful and accompanied by fever. The cause is often foreign body penetration or injection of irritant drugs. Aspiration for cytology and culture and sensitivity testing is warranted if the goat is systemically ill. If encapsulation and abscess formation occur, signs of local inflammation (pain, heat) decrease (Figure 3.1). Given time, many abscesses “ripen” or develop a soft spot in the capsule where rupture is likely to occur. This helps to distinguish an abscess from a hematoma. The hematoma is initially fluctuant but later develops a firm capsule as the blood organizes and resorption begins. Abscesses usually heal rapidly when drainage is supplied. Lancing an abscess at its softest spot reduces both pain and hemorrhage associated with the

surgical procedure. Another, more ventral location may be more appropriate for incision, however, to allow better drainage. Caseous lymphadenitis should be ruled out (by culture or with less certainty by absence of lymph node involvement in any animal in the herd) before the animal with a draining abscess is returned to the herd. Emphysema When crepitation is palpable in subcutaneous or deeper tissues, it is important to determine the origin of the air or other gas that is present. Air may be escaping from the respiratory tract (tracheal laceration, severe pulmonary emphysema) or it may be entering through sucking skin wounds (Tanwar et al. 1983). Attention to the primary problem should stop the inflow of air, and resorption will occur gradually over days or weeks. A crepitant, painful swelling caused by infection of wounds with gas-forming clostridia such as Clostridium chauvoei may lead to death of the animal (van Tonder 1975). The condition can be diagnosed by cytologic examination of aspirates, anaerobic culture, or immunofluorescence testing. Aggressive treatment with systemic and intralesional penicillin is successful in early stages. Gangrenous tissues slough later if the animal survives. In regions where clostridial infections are common, multivalent clostridial vaccines (C. chauvoei, C. septicum, C. novyi) provide inexpensive protection. Edema Pitting edema without crepitation may occur in wounds infected with Clostridium septicum (malignant edema) or C. novyi (swelled head in bucks). Other causes include trauma without tissue infection, frostbite, hypoproteinemia (parasitism, kidney disease, paratuberculosis), and congestive heart failure. Udder edema is discussed in Chapter 14.

LYMPH NODE ENLARGEMENT Although enlargement of one or more lymph nodes in a goat typifies caseous lymphadenitis, other etiologies may be involved. In particular, other bacterial infections may cause hyperplasia or abscessation of the regional node (Gezon et al. 1991). Lymph node enlargement is common in animals with joint infection, including caprine arthritis encephalitis virus infection. Skin diseases such as sarcoptic mange and contagious ecthyma are often accompanied by enlarged nodes. Finally, lymphosarcoma occasionally causes enlargement of external lymph nodes. Caseous Lymphadenitis Figure 3.1. Large, thin-walled abscess in the upper neck of a one-month-old kid from which a Streptococcus sp. was cultured. (Courtesy of Dr. M.C. Smith.)

Caseous lymphadenitis is a chronic contagious disease that mainly affects sheep and goats (Brown and Olander 1987; Williamson 2001) and is increas-

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ingly recognized in camelids (Anderson et al. 2004). The condition occurs worldwide and is well known in many regions of North and South America, Australia, New Zealand, Europe, and South Africa. Etiology Corynebacterium pseudotuberculosis (previously known as C. ovis) is the causative agent of caseous lymphadenitis. Its cultural characteristics are described under diagnosis. Horses are occasionally infected with the organism and may develop ulcerative lymphangitis or chronic abscess, but a different biotype from the one infecting sheep and goats is apparently involved (Aleman et al. 1996). Experimental intradermal inoculation of goats with strains of equine origin has caused abscesses at the injection site and in draining nodes but not in visceral locations (Brown et al. 1985). Most equine strains reduce nitrate to nitrite, whereas small ruminant strains do not.

Clinical Signs The goat without internal abscesses typically shows no clinical signs other than enlargement and abscessation of one or more peripheral lymph nodes (Figure 3.2). Many of the external lymph nodes that may be involved in caseous lymphadenitis are pictured in Figure 3.3. Exactly which nodes are infected depends on the location of the wound that allowed entry of the organism into the body. Thus, most dairy goats (75% to 87%) with external abscesses have lesions on the head and neck (Ashfaq and Campbell 1979a, 1979b; Holstad 1986b; Schreuder et al. 1986) (parotid,

Pathogenesis The organism enters the goat’s body through wounds or small breaks in the skin or mucous membranes and eventually becomes localized in a regional lymph node. Experimentally, tiny abscesses are detectable in lymph nodes by eight days after intradermal inoculation (Kuria et al. 2001). Cell wall lipid permits the organism to resist digestion by cellular enzymes, and C. pseudotuberculosis can survive as a facultative intracellular parasite, even in activated macrophages (Holstad et al. 1989). Sphingomyelin-specific phospholipase D exotoxin produced by the organism is largely responsible for its spread. The incubation period until abscesses are noted in superficial lymph nodes is typically two to six months or longer (Ashfaq and Campbell 1980). These abscesses may rupture and drain spontaneously. The environment and curious herdmates thereby become contaminated, but the initially infected goat’s abscess heals. It is common for one or more additional lymph nodes, following the lymphatic drainage pattern, to develop abscesses several months later. Experimental intradermic inoculation with small numbers of bacteria has demonstrated that spontaneous cures, without abscess rupture but accompanied by development of antitoxin titers, can occur (Langenegger and Langenegger 1988). Internal (visceral) abscesses, especially in the lungs, may develop if the organism reaches the thoracic lymph duct or if it is inhaled. The association of internal abscesses with respiratory disease and wasting disease is discussed in other chapters. Other adverse economic effects of the infection in a herd include decreased market value of stock for sale and of hides from slaughtered goats. Milk production may be decreased.

Figure 3.2. Abscessation of a parotid lymph node due to caseous lymphadenitis. (Courtesy of Dr. M.C. Smith.)

Figure 3.3. Location of common swellings caused by caseous lymphadenitis and caprine arthritis encephalitis. An abscess in the location of external lymph nodes (stippled) suggests caseous lymphadenitis. Enlargement of atlantal or supraspinous bursae (cross-hatched) may occur with CAE.

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Figure 3.4. Abscessation of a popliteal lymph node. (Courtesy of Dr. M.C. Smith.)

mandibular, and superficial cervical “prescapular” nodes), presumably because injuries from thorns, splinters from wooden feeders, combat wounds, and scratching at lice most commonly occur here. Contact of these skin lesions with milking stands, feeders, or scratching posts contaminated by draining abscesses of other goats leads to infected nodes about the head and neck. By contrast, a popliteal lymph node (Figure 3.4) would only become enlarged if infection occurred in the distal hind limb. Mammary lymph node involvement can result from infection of skin lesions on the udder or from mastitis. Slaughterhouse studies typically show the highest prevalence in the prescapular node, among the nodes routinely inspected (Ghanbarpour and Khaleghiyan et al. 2005). Diagnosis Diagnosis of the condition is based on the presence of a firm to slightly fluctuant subcutaneous swelling in the anatomic location of a lymph node (Burrell 1981). In a herd with a history of caseous lymphadenitis, the clinical findings alone are considered presumptive evidence. When a herd history is lacking (no previous veterinary evaluation, assembled herd, individual pur-

chased animal), then laboratory assistance may be indicated for confirming the diagnosis. A sample for culture is obtained by inserting a sterile needle through shaved, disinfected skin into the mass. If aspiration yields nothing, the needle is withdrawn and saline is flushed through the needle to obtain material for a stained smear or culture. Even when the point of skin penetration is intentionally offset from the point where the needle passes through the wall of the abscess, some pus can leak back and serve as a focus of infection to others in the herd. Thus, if pus is present, the lump and the goat should be handled as if caseous lymphadenitis were present (see below) until culture results become available. Cultures of pus from draining caseous lymphadenitis lesions are frequently overgrown by nonpathogenic organisms or secondary invaders such as Proteus species. However, other bacterial infections such as anaerobic Staphylococcus aureus (Alhendi et al. 1993) and Arcanobacterium pyogenes and neoplasia, including lymphosarcoma, must be ruled out if C. pseudotuberculosis is not isolated. The other conditions causing subcutaneous swellings, as discussed in this chapter and reviewed elsewhere (Williams 1980; Fubini and Campbell 1983), also should be considered in the differential diagnosis. The pus in an abscessed node in a goat may be creamy white, yellowish, or greenish; it is typically odorless and is more pasty (less inspissated) than in sheep. A lamellar “onion ring” configuration as seen in sheep with this disease is rarely present in goats (Batey et al. 1986). The organism (a facultative anaerobe) grows readily but slowly on blood agar (Brown and Olander 1987). The colonies are very tiny or invisible after twentyfour hours (Lindsay and Lloyd 1981), and a longer incubation period is recommended before declaring that no growth has occurred. The colonies are still tiny and button-shaped after forty-eight hours, but are surrounded by a narrow zone of hemolysis. The colonies can be easily moved around on the surface of the agar plate and splatter when placed in a flame, because of high content of lipid. The organism is catalase-positive whereas Arcanobacterium pyogenes, which also produces tiny colonies, is catalase-negative (Quinn et al. 2002). Gram-stained smears show Gram-positive or Gram-variable small coccoid rods. A longer rod form is sometimes seen in smears of pus. Serologic tests such as the bacterial agglutination test and synergistic hemolysis-inhibition (SHI) test (Zaki 1968; Brown et al. 1985,1986b; Holstad 1986a) are valuable in identifying goats with early or internal forms of caseous lymphadenitis. The SHI test is commercially available in the United States, through the University of California, Davis, and several other laboratories, and has a sensitivity of 98% in goats (Brown and Olander 1987). However, in the same study popu-

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lation, 28% of goats with no demonstrable abscess were also SHI positive, indicating a lack of specificity. Laboratory personnel report that a titer of 1:256 or greater correlates well with internal abscesses, but that occasionally an animal with a walled-off abscess tests negative. Experimental infections have not been detectable serologically until at least fifteen days after infection (Kuria et al. 2001), so purchased animals should be retested at the end of their quarantine period. Colostrally derived antibodies may cause false positive test results in kids under six months of age (Williamson 2001). Also, most tests have not been specific enough for current infection to justify their use in culling programs (Ellis et al. 1990). A decreasing titer on a retest taken two to four months after the first sample suggests that an active infection is not present. An ELISA test to detect antibodies against exotoxin and used for disease eradication in the Netherlands (Dercksen et al. 1996) has recently been improved to increase sensitivity to 94%, specificity of 98% (Dercksen et al. 2000). Because the organism is a facultative intracellular pathogen, cell mediated immunity is involved in the immune response. Preliminary work with a commercially available bovine interferon gamma ELISA (Bovigam, Pfizer Animal Health) for cell mediated immunity to C. pseudotuberculosis has suggested that it is sensitive to prior infection and is unaffected by vaccination (Menzies et al. 2004). Caprine interferon gamma cross-reacts in the assay. This test may be useful to detect carriers in vaccinated herds, although it may not reflect the extent of the infection. The increases in total serum proteins and gamma globulin that are reported for goats with caseous lymphadenitis (Desiderio et al. 1979) are also nonspecific. An intradermal allergic test using a water-soluble protein “lymphadenin” has been used to differentiate goats with abscesses from uninfected goats (Langenegger et al. 1986). Injections were made in the shoulder region and the maximum increase in skin-fold thickness occurred after forty-eight hours. Surgical Treatment Treatment of individual animals involves either draining or surgically removing the abscessed nodes. Ripened abscesses can be incised generously at a ventral point and the cavity flushed with dilute disinfectant. Because the infection is potentially zoonotic, people performing this procedure should wear gloves. The pus should be collected and burned and the goat should be kept strictly isolated until the lesion is completely covered by healthy skin, typically twenty to thirty days later (Ashfaq and Campbell 1980). Allowing an abscess to rupture in the main goat pen or returning the animal to the herd where herd mates will lick the wound will only serve to contaminate the environment and spread the infection. Stanchions, milking

stands, and keyhole feeders in particular will become contaminated. The advantages of surgical removal of the encapsulated abscess are that the treated animal does not need to be quarantined afterward and spread to other nodes is less likely to occur, but veterinary expertise is required and there are dangers associated with anesthesia and dissection near large blood vessels and cranial nerves. Extirpation of abscessed parotid nodes is particularly dangerous, and treatment of a retropharyngeal abscess requires marsupialization. An alternative but controversial treatment for carefully chosen abscesses is to inject them with 10% formalin at the point where the ripening abscess has become fixed to the overlying skin. A 16-gauge needle is used and approximately 20 ml of formalin is repeatedly injected into and withdrawn from the abscess until the cloudiness of the formalin/pus mixture in the syringe is no longer increasing; larger abscesses require a larger initial volume of formalin. This causes sloughing of the node within a few weeks but raises specters of meat or milk contamination or carcinogenesis in the minds of many veterinarians. Formalin is rapidly converted to formic acid, and formate is an intermediate in normal metabolism in the body. If the abscess is not fixed to the skin, formalin leaking out of the injected abscess will damage surrounding tissues as well as cause pain to the animal. Antibiotic Therapy In the past, long-term treatment with antibiotics or isoniazide of abscesses inaccessible to surgical management has not been rewarding. Antibiotic sensitivity testing is of little benefit, because most antibiotics do not penetrate into the abscessed lymph node and the organism itself may be intracellular. Administration of penicillin or tetracycline for a few days after spontaneous rupture or lancing of an abscess is suggested to prevent dissemination of the organism to other lymph nodes, but the value of this treatment has not yet been determined in controlled clinical trials. Success in treating foal pneumonia caused by Rhodococcus equi with a combination of erythromycin and rifampin led to renewed interest in medical treatment of valuable sheep and goats. Pharmacokinetic data derived from other species suggest that an oral dose of 10 to 20 mg/kg rifampin s.i.d. might be appropriate (Sweeney et al. 1988; Frank 1990; Jernigan et al. 1991). A possible erythromycin dosage is 4 mg/kg administered intramuscularly or subcutaneously. Because erythromycin is highly irritating, a rifampin/penicillin combination might be preferable. Treatment should be continued for four to six weeks. Reports of the efficacy of rifampin in goats with caseous lymphadenitis are not yet available. One report of rifamyin at 10 mg/kg IM b.i.d. for ten days combined with long-acting oxytetracycline at 20 mg/kg IM every third day gave a

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promising reduction in the size of affected lymph nodes, though the animals were only followed for one month (Senturk and Temizel 2006). There is no information available for estimation of meat or milk withdrawals to avoid antibiotic residues after the use of rifampin. More recently, azithromycin has become popular for treatment of rhodococcal pneumonia in foals because of good intracellular penetration and long half-life (Chaffin et al. 2008), and the pharmacokinetics of this antibiotic in goats have been studied (Carceles et al. 2005). Again, to date there is no information on efficacy, dose, or withdrawal times if azithromycin is used in goats with caseous lymphadenitis. Herd Eradication and Control Programs Eradication of caseous lymphadenitis from a herd is difficult. The owner must be willing to cull goats and sheep with multiple abscesses and forgo purchase of animals from infected herds. Introduction of the disease into the United Kingdom by imported goats has underscored the risks associated with an open herd status (Gilmour 1990; Lindsay and Lloyd 1991). Ideally, a negative serologic test should be required before purchase, even from a herd believed to be free of the disease. Newly acquired animals, including camelids, should be examined for lymph node enlargement at least monthly for one year or more after arrival. An eradication program based on culling of serologically positive animals was successful in fifty-three herds (approximately 13,000 adult goats) in the Netherlands (Dercksen et al. 1996). Valuable infected animals may be kept isolated; their kids should be removed at birth and fed heattreated or bovine colostrum to avoid transmission of the disease as the newborn searches for the udder. Commercial pasteurization is known to kill C. pseudotuberculosis in milk (Baird et al. 2005). Division of an enzootically infected herd into infected and apparently uninfected groups has also been proposed as a means of limiting spread (Mullowney and Baldwin 1984). The housing facilities should be free of nails, wire, and other objects that might induce breaks in the skin. Control of external parasites is very important because pruritic goats will rub themselves on nails and posts. Needles, tattooers, and surgical instruments should be sterilized between animals. Shearing equipment that has been used on another farm should likewise be disinfected. All wounds should be treated promptly with a disinfectant, and the umbilical cords of kids should be dipped in iodine at birth. In infected herds of Angora or Cashmere goats, animals should not be dipped for control of external parasites during the two weeks immediately after shearing; topical pour-on insecti-

cides can be substituted. Animals with chronic respiratory disease or wasting should be culled, or at least isolated from the herd. Natural transmission from lung lesions via discharge of pus into airways has been demonstrated in sheep (Ellis et al. 1987). An environment contaminated with pus may be the source of new infections for weeks or months. Recovery of the organism from wood surfaces, straw, hay, and soil has been demonstrated by various researchers (Augustine and Renshaw 1986; Brown and Olander 1987). Thus, the isolation facilities used to contain a goat after rupture or lancing of an abscess should have a concrete floor. The bedding should be burned and the pen thoroughly cleaned (pressure washed) and disinfected between animals. In a successful herd eradication program in Norway, housing areas used by infected animals were left vacant for three months after disinfection and the upper 10 cm of soil in the paddocks was removed to decrease the risk of soilborne infection (Nord et al. 1998). Vaccination Numerous studies using mice have evaluated immune responses to the organism. Cell-mediated immunity has been demonstrated to restrict bacterial proliferation. Neutralization of exotoxin (phospholipase D) produced by the organism is believed to limit spread from the primary site of infection. The value of vaccination as an aid in controlling the disease in ruminants has been frequently questioned. A decrease in the prevalence of abscesses in the herd has often been noted where autogenous bacterins have been used, but concerned owners have simultaneously culled known infected goats and generally improved hygienic measures. As a note of caution, if not properly prepared and tested, an autogenous vaccine against this organism may contain enough free toxin to kill the vaccinated goat. The SHI test does not distinguish between naturally infected and vaccinated goats unless serial tests are compared, so test and cull is difficult to use once a vaccination program has been implemented. Likewise, vaccinated goats test falsely positive in an ELISA for antibodies against exotoxin and cell wall antigens (Sting et al. 1998). A commercial vaccine (Glanvac®, Commonwealth Serum Labs, Melbourne, Australia) developed in Australia has been evaluated in goats (Anderson and Nairn 1984a, 1984b; Brown et al. 1986a). This product is a formalinized exotoxin with incomplete Freund’s adjuvant. In one study, challenge by swabbing a live culture onto abraded skin revealed that either one or two doses of vaccine gave good protection; three of twenty vaccinated goats developed abscesses, as compared to ten of ten control goats (Anderson and Nairn 1984a). Colostrally derived immunity protected young kids against challenge (Anderson and Nairn 1984b). In

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enzootically infected herds, serologic titers in kids disappear by three to four months of age, only to reappear after exposure to the organism. Vaccination should probably be performed before four months of age (Holstad 1986c), but colostrally derived antibody may interfere when vaccination is begun before three months (Paton et al. 1991). A different commercial vaccine (Case-Bac® and Caseous-DT®, Colorado Serum Co., Denver, CO) is available in the United States. This bacterin-toxoid preparation is only labeled for sheep, where its efficacy has been documented (Piontkowski and Shivvers 1998), but it has been used on goats. There are numerous anecdotal reports of adverse reactions including severe milk drop, lameness, anorexia, fever and depression for one to two days after vaccination in adult dairy goats in infected herds, but many owners and practitioners report that vaccination of young stock beginning at two or three months of age has been helpful in reducing disease prevalence. Vaccination should probably be continued for many years, because of the possibility that one or more members of the original herd remain carriers and shedders of the organism. Field evaluation of crude filtrated C. pseudotuberculosis toxoid combined with whole killed cells has been disappointing in goats (Holstad 1989), whereas another experimental whole cell vaccine gave a nonstatistically significant trend for fewer cases in the vaccinated goats in a field trial in Canada (Menzies et al. 1991). A formalin-inactivated whole cell vaccine with aluminum gel phosphate adjuvant gave partial protection (estimated at 77%) in a field trial under extensive conditions in Brazil (Ribeiro et al. 1988). Whole cell preparations of the organism adjuvanted with mycobacterial components have been evaluated (Brogden et al. 1990). A modified live intradermal vaccine has been developed by EMBRAPA in the State of Bahia, Brazil. Zoonotic Potential Human lymphadenitis caused by Corynebacterium pseudtotuberculosis has been reported, especially from Australia (Peel et al., 1996; Mills et al. 1997). The course was often protracted and diagnosis delayed until a culture was performed. Recovery usually required surgical removal of the affected lymph node, with supplemental antibiotics. Owners, slaughterhouse workers, and veterinarians should handle infected animals and abscesses with caution. Melioidosis In tropical areas such as Southeast Asia, Malaysia, the Netherland Antilles, and parts of Australia, a zoonotic disease caused by Burkholderia (Pseudomonas) pseudomallei is seen in goats and must be differentiated from caseous lymphadenitis. The disease seen in

humans has been reviewed recently (Cheng and Currie 2005). Etiology Burkholderia (Pseudomonas) pseudomallei is a Gramnegative bacillus with polar flagella that may show bipolar staining. It closely resembles P. aeruginosa. The organism may be cultured on sheep blood agar or MacConkey agar (up to four days at 37°C). Some strains are hemolytic. Epidemiology and Pathogenesis The organism resides in soil and contaminated water. Survival in soil for up to thirty months has been reported (Thomas and Forbes-Faulkner 1981). Infected animals, including rodents, pass the organism in feces. Spread from animal to animal by biting insects also occurs. Vertical transmission is possible, as natural and experimental infection of pregnant goats has led to infection of aborted and live born kids (Retnasabapathy 1966; Thomas et al. 1988a). Clinical Signs Initial bacteremia is followed by formation of abscesses and granulomas in superficial lymph nodes, lung, and other internal organs. Prescapular lymph nodes are commonly involved and contain grayish yellow, creamy pus (Sutmöller et al. 1957). Chronic mastitis (van der Lugt and Henton 1995), weight loss, polyarthritis, and meningoencephalitis are also reported. Diagnosis and Control The indirect hemagglutination test (positive at 1/40 or higher) is considered most suitable for screening, because it has a sensitivity of 98%. The 100% specific complement fixation test (positive at 1/8 or higher) is used for confirmation (Thomas et al. 1988b). Sensitivity of the complement fixation test is lowered (82%) in chronic infections. The final diagnosis is made by culture. Older lesions in goats are sometimes sterile (Thomas et al. 1988b). Antibiotic treatment is ineffective. Infected goats are to be eliminated and the herd monitored by serologic testing (Baxendell 1984). Other Infectious Agents Goats with arthritis because of a variety of causes may have enlargement of the associated lymph node. Regional lymph node enlargement is a constant finding with caprine arthritis encephalitis virus infection (Robinson and Ellis 1986), which is a common cause of lameness and enlarged joints in dairy goats in North America, Europe, and Australia. The reader should refer to Chapter 4 for an in-depth discussion. Dermatophilus congolensis, a Gram-positive organism that forms branching filaments in pus, has been

68 Goat Medicine

isolated from abscessed superficial lymph nodes of Beetal goats. Other breeds housed with infected goats were not involved (Singh and Murty 1978). This organism more typically causes a superficial dermatitis. Goats with contagious ecthyma (soremouth) virus infection may have noticeable enlargement of lymph nodes draining the head. Mange can also cause marked lymph node enlargement. See Chapter 2 for discussion of skin diseases. In regions where trypanosomiasis is endemic, Trypanosoma brucei, and to a lesser extent, T. congolense and T. vivax, cause a marked lymphadenopathy in goats. Theileria is another blood-borne parasite that causes enlargement of lymph nodes. These diseases are discussed in Chapter 7. Infectious agents causing mastitis (including tuberculosis) may cause enlargement of the supramammary lymph nodes and are discussed in detail in Chapter 14. Lymphosarcoma Lymphosarcoma in goats is a neoplastic disease of unknown etiology. It has many similarities to sporadic or juvenile bovine lymphosarcoma. Neither the bovine leukemia virus nor antibodies against that virus associated with adult bovine lymphosarcoma have been found in goats with naturally occurring lymphosarcoma, although one experimentally produced goat case has been reported (Olson et al. 1981). Lymphadenopathy of superficial nodes is not a consistent finding; only three of ten goats in one report were thus affected (Craig et al. 1986). In these animals, a lymph node aspirate yielding many lymphoblasts might confirm the diagnosis (Duncan and Prasse 1986). However, as least in cattle, fine needle aspirates have relatively low sensitivity for diagnosis of lymphosarcoma (Washburn et al. 2007). Goats affected with lymphosarcoma are generally older than two years of age. They may have a variety of clinical signs, including high fever, emaciation, diarrhea, or dyspnea. The organs most frequently involved are liver, spleen, lungs, and lymph nodes, although the reproductive tract has also been involved (DiGrassie et al. 1997). Rapid deterioration occurs when clinical signs are noted, with death or euthanasia supervening in one week to two months in most cases. This is in contrast to the long and usually benign course of external caseous lymphadenitis.

SWELLINGS INVOLVING THE HEAD A number of specific conditions are limited to the head or neck. These are discussed below and some of them can be located with the aid of Figure 3.5. Retention of a Cud in the Cheek Contented goats frequently have a bulge in the cheek region during rumination. The swelling disappears as soon as mastication is complete or the goat is startled. If such a swelling persists and is found on careful digital examination to consist of a cud rather than a thickening of the cheek (abscess), neurologic dysfunction, a tooth problem, or some other condition interfering with mastication or swallowing should be suspected. Tooth Problems Absent, irregular, or abscessed teeth may lead to improper chewing and accumulation of feedstuffs or cuds between the dental arcade and the cheek. These problems are discussed below and in Chapter 10. Facial Nerve Paralysis Cud retention may indicate facial nerve paralysis, and thus should prompt a thorough neurological examination (see Chapter 5). Deviation of the philtrum, drooling, inability to blink, and drooping of the pinna may also be present. Conditions to be considered in differential diagnosis include traumatic injury to the facial nerve, otitis media, listeriosis, and other lesions involving the brain stem. Of these, listeriosis

Prominent Lymph Nodes of Normal Size A distinction must be made between increased size and increased ease of palpation of lymph nodes. Animals that are emaciated because of malnutrition, parasitism, or chronic infectious diseases have very prominent nodes because subcutaneous fat is absent.

Figure 3.5. Swellings involving the head or neck: (1) cheek abscess or cud retention, (2) salivary mucocele, (3) tooth root abscess, (4) bottle jaw, (5) thyroid gland, (6) thymus gland, (7) wattle cyst.

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should receive special consideration, because the disease is most apt to be successfully treated if clinical signs are limited to peripheral nerve dysfunction. Salivary Mucocele Painless swellings on the side of the face sometimes are cystic structures filled with saliva. Anatomy and physiology The parotid salivary glands of the goat are roughly rectangular and extend from the ear to the bifurcation of the jugular vein. Each parotid duct runs subcutaneously across the lateral surface of the masseter muscle near its ventral border. It empties into the mouth via the parotid papilla, which is opposite the upper fourth premolar or first molar (Habel 1975). The mandibular salivary glands are triangular in shape. They lie deep to the parotid gland and caudal to the mandibular lymph node, along the medial side of the angle of the mandible. The mandibular ducts, which are less accessible to injury than the parotid ducts, go to the medial side of each sublingual caruncle. The monostomatic ducts of the sublingual glands open on the lateral side of each sublingual caruncle. Sialography can be performed (Tadjalli et al. 2002). In addition to these major paired glands, there are diffuse layers of salivary gland tissue in the walls of the mouth and pharynx. The salivary glands of ruminants secrete continuously. The saliva is slightly alkaline, because of its high concentration of bicarbonate. The physiologic function of saliva is discussed in Chapter 10. Etiology Blockage or rupture of a duct can lead to formation of a salivary mucocele. Forceful restraint of the head of young kids against a metal brace during disbudding has led to mucocele formation. It is also important to avoid damaging the glands or the parotid ducts in surgical operations involving the head and neck, in particular drainage or extirpation of abscessed lymph nodes. Painless fluid-filled cysts have been reported on the side of the face or in the submandibular region of young Nubian goats. These cysts were found to be lined by pseudostratified columnar epithelium containing goblet cells. Parotid salivary gland duct epithelium appears similar, and thus these cysts were presumed to be developmental anomalies (Brown et al. 1989). Figure 3.6 shows a one-month-old Nubian kid that had fluid-filled cysts bilaterally at birth. These cysts, which appeared to be outpocketings of a salivary duct, were removed surgically and the ducts ligated. Clinical Signs and Diagnosis Aspiration of the soft, fluctuant, nonpainful swelling should yield a clear, watery or slightly blood-tinged

Figure 3.6. Congenital salivary gland duct cyst in a Nubian kid. (Courtesy of Dr. R.P. Hackett.)

mucoid fluid that is colorless and odorless. The pH level is higher than that of blood. Confusion with a tapeworm cyst over the mandible, as discussed below, might be possible (Ghosh et al. 2005). Treatment Salivary cysts can be excised, as long as the caudal portion is ligated to occlude the parotid salivary gland duct. Excision of the gland itself is not required (Brown et al. 1989). Such swellings should not be lanced, because a chronic fistula and continuous loss of saliva may result. The discharge is not only aesthetically displeasing; the loss of bicarbonate, which approaches 30 to 50 grams per day in experimentally cannulated sheep, can lead to life-threatening acidosis. Abscess Subcutaneous abscesses on the head, as elsewhere on the body, may involve a variety of organisms, including Corynebacterium pseudotuberculosis, Arcanobacterium pyogenes, Escherichia coli, and staphylococcal and streptococcal species (Ashfaq and Campbell 1979b). Nocardia has also been isolated from chronic subcutaneous abscesses on the face and elsewhere on the body (Jackson 1986). An anaerobic staphylococcus has been associated with a herd outbreak of subcutaneous abscesses involving the head in goats in the Sudan (El Sanousi et al. 1989). From Biting Cheek When an abscess is located in the cheek, exactly where upper and lower molar teeth meet, the possibility of a self-inflicted injury with contamination by bacteria in the oral cavity must be considered. Filing of exceptionally sharp points on the teeth may be justified to avoid recurrence. Manual restraint of a

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goat’s head in such a way that skin of the cheek is forced between the molar arcades (as when teaching a kid to drink from a bucket) and tight halters should be avoided. From Other Wounds Wounds in the skin or oral mucosa may result from puncture by thorny vegetation or from grass awns. Bite wounds by predators or more dominant goats also offer a portal of entry for pyogenic organisms. In general, identifying the exact microorganism involved is not important, other than for ruling out caseous lymphadenitis. Draining and then flushing the abscess with dilute iodine usually provide adequate therapy. Systemic penicillin is given if the goat is systemically affected or the lesion is especially large. Actinobacillosis is somewhat different in that Actinobacillus lignieresii causes multiple chronic, firm, nodular lesions, often with draining tracts in sheep. The lesions are located in soft tissues of the head or in the regional lymph nodes. The presence of small (less than 1 mm in diameter) granules in the pus is quite suggestive of actinobacillosis but unfortunately they are not often seen. Confirmation requires culture of the organism. Sulfonamides, streptomycin (not available in the United States), and sodium iodide have been recommended for treatment; penicillin is not effective. The occurrence of actinobacillosis in goats has not been documented. The condition is commonly seen in sheep flocks free of C. pseudotuberculosis and can be mistaken for caseous lymphadenitis, resulting in unnecessary culling if cultures are not performed. From Dehorning Dehorning represents a special wound that may become infected and eventually develop into an abscess beneath the eschar from heat cautery or the bandage or scab from surgical horn removal. This condition is discussed below under sinusitis. Tooth Root Abscess As a sequel to periodontal disease (perhaps from feeding coarse hay or hay containing grasses with barbed awns), foreign material gets between the tooth and gum and an abscess may form around the root of a molar tooth. In the authors’ experience this occurs most often in the lower jaw and is accompanied by decreased hay consumption and difficulty cudding. The infection progresses until bony distortion of the ventral ramus is noted (Figure 3.7). The swelling is easily detected by comparing the thickness of the mandibles while palpating with the thumb and forefinger of each hand. This ventral swelling may break and drain pus. An oral exam (with xylazine tranquilization) should be conducted to identify obviously broken or loose teeth that need to be extracted. More typically,

Figure 3.7. Tooth root abscess involving the mandible. (Courtesy of Dr. M.C. Smith.)

the tooth involved can only be identified with an oblique radiograph of the jaw. Some of these goats respond to repeated iodine flushing of the draining tract and three to four weeks of penicillin or florfenicol or some other antibiotic selected on the basis of culture and sensitivity. A pelleted hay product encourages feed consumption during the initial stages of therapy because extensive chewing is not required. Although surgical extraction of the involved tooth has not been reported in the caprine literature, experience with other species suggests that this might be the preferred treatment if accomplished without fracture of the mandible. Oral extraction would be very difficult (if the tooth is not loose) because of poor exposure, and consideration should be given to osteotomy of the lateral mandibular plate, as is described for llamas and small exotic ruminants (Turner and McIlwraith 1989; Wiggs and Lobprise 1994; Niehaus and Anderson 2007). After the tooth is repelled into the mouth, a pack of dental acrylic will exclude food particles from the surgery site. Actinomycosis Lumpy jaw (Actinomyces bovis) apparently is very rare in goats (Baby et al. 2000; Seifi et al. 2003). Involvement of bone and presence of sulfur granules raises the suspicion of this infection. Treatment is as for actinobacillosis, with five to seven days of streptomycin if available (10 mg/kg twice or three times daily) combined with oral iodides as a possible protocol. Daily subcutaneous injections of oxytetracycline at 20 mg/ kg can be substituted. Important conditions to consider in differential diagnosis are tooth root abscess,

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osteodystrophia fibrosa, and invasion of the jaw bones by lymphosarcoma (de Silva et al. 1985; Craig et al. 1986; Guedes et al. 1998; Rozear et al. 1998). Osteodystrophia Fibrosa A marked bilateral enlargement of the mandible has been reported in young (and occasionally adult) goats consuming mostly concentrate and thus having excessive phosphorus relative to calcium in the diet. The mandibles are soft (readily penetrated by a needle) and the cheek teeth are rotated so that the crowns are directed toward the tongue (Andrews et al. 1983). Demineralization is evident on radiographs (Singh 1995). In advanced cases, it may be impossible to open the mouth. Spontaneous fractures may occur. Feeding a good hay (such as alfalfa, which is high in calcium) and restricting the grain should prevent this condition, which is discussed in more detail in Chapter 4. A similar mandibular (and maxillary) osteodystrophia fibrosa has been observed in four goats on a longterm (472 days) feeding trial with Leucaena leucocephala. The calcium to phosphorus ratio was more than 6:1. The kidney, thyroid, and parathyroid were histologically normal, and occurrence of the condition was not explained (Yates et al. 1987). Chronic renal disease might result in similar bone lesions. Bottle Jaw The presence of fluctuant pitting edema in the intermandibular space of goats that are not obviously in heart failure should arouse the suspicion of endoparasitism (see Chapter 10). The edema results from hypoproteinemia, which follows blood and plasma loss caused by nematode infestations of the gastrointestinal tract and liver failure in fluke infestation. Paratuberculosis also can cause severe enough hypoproteinemia to manifest as bottle jaw, as can renal disease. These conditions are discussed in Chapters 10, 11, and 12. Swelled Head of Bucks Fighting bucks may develop severe edematous infections of the head in regions where Clostridium novyi is prevalent. Other clostridia including C. chauvoei, C. sordelli, and C. septicum may be involved. The swelling begins near the horns and eyes but may extend down the face, neck, and chest. Tissues are full of yellow fluid and clostridia may be demonstrated on smear or anaerobic culture. Lymph nodes are swollen. The animal is lethargic and febrile. Death usually occurs within one to two days unless the swellings are opened surgically to allow oxygenation and massive doses of antibiotics (penicillin) are given. Photosensitization (see Chapter 2) might appear similar but does not spare the ears and is less rapidly fatal (King 1984). Bucks with a simple seroma on the poll from fighting will not be systemically ill.

Deformation of the Cranium An abnormal profile of the cranial bones suggests hydrocephalus in the neonate and sinusitis or parasitic cyst in the older goat. Hydrocephalus Occasionally kids are born with an obvious doming of the skull and congenital hydrocephalus. This is usually sporadic, with no known predisposing cause, although some kids congenitally infected with Akabane virus (see Chapters 4 and 13) have hydrocephalus. The hereditary lysosomal storage disease of Nubians, beta mannosidosis, is also accompanied by deformation of the cranium, and is discussed in Chapter 5. Kids with hydrocephalus should be euthanatized if neurologic abnormalities are severe enough to interfere with nursing or locomotion. Sinusitis Except in neonatal kids, surgical dehorning invariably opens the frontal sinuses, into which hay and other foreign matter may easily fall. If a scab closes the opening before any infection present is eliminated, it is possible for an abscess to develop that may eventually lead to softening and distortion of overlying bone. A history of open dehorning within the last six months would be suggestive. Careful percussion may demonstrate a relative dullness over the affected sinus. Radiographic evaluation is recommended if there is any doubt that the swelling is over the frontal sinus rather than the cranial cavity or tooth roots. Drainage should be established and the sinus flushed daily, after removal of any foreign material or necrotic bone. Enzootic intranasal tumor and lymphosarcoma, as discussed in Chapter 9, can invade the sinuses and cause bony distortion of the face. Digital pressure on softened bone causes expulsion of a seromucous exudate from the nostrils when an enzootic intranasal tumor is present (De las Heras et al. 1991). Decreased airflow is detectable through the nostril on the affected side. A dorsoventral radiograph reveals the space occupying nature of the tumor. Coenurus Cerebralis (Gid) Coenurus cerebralis is the larval form of the canine tapeworm Taenia multiceps. It can form cysts in the parenchyma of the brain or on its surface in sheep and goats. Blindness or various other neurologic signs occur, depending on the exact location of the cyst. The overlying skull may bulge and soften or even perforate. Where this sign is relied on for diagnosis it is reported to be common (Sharma and Tyagi 1975), although many affected animals show no outward changes in the skull. Insertion of an 18-gauge needle through the softened bone yields clear fluid under pressure, and

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sometimes the cyst can be extracted from the cranium by aspiration through a tube inserted via this needle. At least one goat has been cured by injecting Lugol’s solution into the cyst. A more detailed discussion of this parasite is supplied in Chapters 5 and 6. The parasite may no longer be present in the United States.

SWELLINGS INVOLVING THE NECK AND CHEST Caseous lymphadenitis, as already discussed, should always be considered when swellings are present in the region of cervical or prescapular lymph nodes. Many other conditions of varied etiology cause diffuse or localized swellings on the neck or chest. Abscesses Other Than Caseous Lymphadenitis Abscesses that do not respond to simple drainage should be reassessed (including radiographic examination) for possible presence of a foreign body such as a needle, plant fragment, or piece of necrotic bone. Abscesses in the neck and near the left elbow have been reported in goats that ingested sewing needles (Sharma and Ranka 1978; Tanwar and Saxena 1984). Mycetomas, as discussed in Chapter 2, are chronic, subcutaneous, fungal-induced swellings, often with underlying periosteal reaction. Tissue Necrosis (“Sterile Abscesses”) Caused by Injections A number of vaccines, including multivalent clostridial (Green et al. 1987), paratuberculosis (Holstad 1986d), caseous lymphadenitis, and foot and mouth disease vaccines, cause large, roughly spherical, firm, persistent swellings (granulomas). This occurs in most of the animals vaccinated and does not require contaminated vaccine or dirty needles to occur. A provisional diagnosis is based on the presence of such a tissue reaction in a site known to have been used previously for vaccination. No treatment is required in commercial animals unless local infection occurs. These swellings are of more concern in pets and show goats, where surgical extirpation of the lump may be requested by the owner. It is important to inject these animals in a cosmetically acceptable location, such as behind the shoulder or elbow, because a reaction can be expected from many adjuvanted, effective vaccines. In general, injections should not be given subcutaneously in the neck of a show animal. It is difficult for veterinarians writing health certificates to feel confident that goats with a nodular swelling in this region are free of caseous lymphadenitis. Administering vaccines and antibiotics deep into musculature is not a satisfactory method of avoiding problems. The result, an often severe necrosis of muscle, is more difficult to observe but clearly painful to the goat. Tender, firm swellings, lameness, or reluc-

tance to rise are common. When a site in the hind limb is used, sciatic nerve paralysis is also common, especially in young or emaciated animals with limited muscle volume. In addition, if the animal is to be used for meat, the muscle necrosis, which outlasts tissue residues by weeks or months, results in carcass damage that requires trimming or that escapes the notice of the meat inspector but is obvious and unappealing to the consumer. Certain solutions are so irritating to tissue that they should not be administered subcutaneously or intramuscularly to goats. Some proprietary calcium preparations with phosphorus and dextrose included are noted for causing sloughing of tissue at the injection site. Failed attempts at intravenous injection may cause large swellings over the jugular vein where irritating drugs were mistakenly deposited in a perivascular location. In animals kept for antibody production, it is normal to find numerous firm subcutaneous nodules where the adjuvanted antigen has been injected. Wattle Cyst and Thyroglossal Duct Cyst Wattles are reportedly caused by a dominant autosomal gene with complete penetrance but variable expression regarding the shape and location of the wattles (Ricordeau 1981). Occasionally, cysts occur unilaterally or bilaterally at the base of the wattle or at the site of previous wattle amputation. These cysts are certainly not rare but rarely are of enough concern to be reported in the literature. They are variously referred to as branchial cleft cysts (Williams 1980), dermoid cysts (Gamlem and Crawford 1977), or wattle cysts (Fubini and Campbell 1983). Wattle cysts are usually present at birth, although they may enlarge with time and become more noticeable later. They contain a thick or thin clear liquid and refill or become abscessed after aspiration. They can be excised intact under local anesthesia if care is taken to avoid the underlying jugular vein; excision may be necessary in show goats because of possible confusion with caseous lymphadenitis. Breed predilections reported in the literature may be biased by the prevalence of given breeds or family lines in certain regions. Wattle cysts should be differentiated from thyroglossal duct cysts that are located on the midline, below the hyoid apparatus (Al-Ani and Vestweber 1986; Nair and Bandopadhyay 1990; Al-Ani et al. 1998). Thyroglossal cysts sometimes become quite large over time and can be removed surgically with due care. Thyroid Gland and Goiter Anatomy and Physiology The thyroid of the goat is bilobed and located slightly behind the larynx. Right and left lobes, which

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lie lateral to the trachea, are joined by a thin isthmus that passes across the ventral aspect of the trachea (Reineke and Turner 1941). In young animals, the lobes of the thyroid gland are often embedded in thymic tissue. The isthmus becomes more fibrous (less glandular) and more caudally located with advancing age (Roy et al. 1975). The thyroid gland forms several hormones by iodinating organic compounds that contain the amino acid tyrosine. Thyroxine (T4) and 3,5,3-triiodothyronine (T3), when formed, are stored in colloid within the acini of the thyroid gland until needed. The thyroid gland and its hormones control the metabolic rate of an animal by regulating cellular oxidation (Wilson 1975). Selenium is required for hepatic conversion of T4 to T3 (Köhrle 2000). Goiter is an enlargement of the thyroid gland. In ruminants, goiter usually suggests attempted compensation for a hypothyroid state. Normally, low thyroxine and triiodothyronine output stimulates increased thyrotropin (thyroid-stimulating hormone) output, which leads to increased iodine uptake from the blood and hyperplasia of the gland. The enlarged gland may be able to compensate by increased iodine trapping. Normal Thyroid Function Tests Natural hypothyroid states other than goiters have not been reported in goats. If testing is done, it should be remembered that, at least in dogs, corticosteroid therapy and the terminal stages of nonthyroidal illnesses can both depress plasma T4, possibly because of interference with T4 binding by plasma proteins. The thyroid function of goats has been investigated by researchers wishing to use the species as a model for the physiology of larger ruminants. For instance, uptake of radioiodine (131I) has been studied in goats (Flamboe and Reineke 1959; Davis et al. 1966; Ragan et al. 1966). Thyroidectomy, as discussed below, has also been performed to study normal thyroid function. Thyroid hormone level determinations are more accessible to practitioners, although caprine normals are not well established. Repeated serum thyroxine level determinations in twenty female and forty male goats of dairy breeds, from two weeks to six years of age, yielded a mean of 6.53 ± 0.03 (SE) μg/dl of thyroxine. The range was 2 to 17 μg/dl (Anderson and Harness 1975). Thyroid function tests were also performed on up to fifty-five pygmy goats from a laboratory colony (Castro et al. 1975). No sex differences were noted. Mean values recorded included: protein bound (organic) iodine, 8.1 ± 1.2 (SD) μg/dl; T4, 7.2 ± 1.1 μg/dl; and cholesterol, 90 ± 29.7 mg/dl. Because values were within normal human ranges, the authors concluded that there was no evidence of thyroid malfunction.

As part of a study to establish normals for ten species, thyroid hormones were assayed in duplicate from ten goats (Reap et al. 1978). Average values (± standard deviation) and ranges were: T4, 3.45 ± 0.47 (3 to 4.23) μg/dl and T3, 145.9 ± 29.32 (88 to 190) ng/dl. The average thyroxine value for four young and four adult goats (breed not specified) was 4.25 μg/dl in another study (Kallfelz and Erali 1973). Thyroxine levels in Angoras in South Africa were found to fluctuate with no obvious seasonal pattern (Wentzel et al. 1979). In one study of dairy goats, the plasma thyroxine level decreased by approximately 30% during the first week of lactation, relative to the prepartum period (Emre and Garmo 1985). The author has evaluated thyroid-stimulating hormone response in three normal adult dairy goats (M.C. Smith, unpublished data). Serum thyroxine concentrations approximately doubled four hours after intravenous injection of 5 IU of thyrotropin. A similar response was seen in 25 juvenile goats after receiving intravenous thyrotropin releasing factor at 1 μg/kg; T3 increased a mean of 318% at one hour and T4 increased a mean of 174% (97% to 227%) at four hours after stimulation (Reinemeyer et al. 1991). Baseline values in this study were 30 to 90 ng/dl T3 and 3.1 to 6.1 μg/dl T4. Experimental Hypothyroidism Thyroidectomy has been performed in the goat. Ectopic thyroid tissue can be destroyed by 131I administration where surgical removal of the visible thyroid glands is not sufficient (Ekman 1965). Parathyroid function is maintained because a pair of external parathyroids is located separately from the thyroid glands, embedded in thymic tissue. When adult goats underwent thyroidectomy, the major clinical sign was body weight gain. Does that received 131I during pregnancy produced stillborn kids with no detectable thyroid glands. These does had reduced milk production. Goats that underwent thyroidectomy developed marked thickening and softening of the skin with local hair loss and they shivered intensely when exposed to cold (Andersson et al. 1967). When young kids underwent thyroidectomy, growth stopped within one to two months, kids became lethargic, and the head developed a dish-faced appearance (Reineke and Turner 1941). Growth recommenced if iodinated proteins were fed. Goats with hypothyroidism have also been created experimentally by daily oral feeding of thiourea (Sreekumaran and Rajan 1978) and by injection of methyl thiouracil or thiourea (Gupta et al. 1990). When young kids were thus treated, weight loss and myxedema (edema and gelatinous infiltration of subcutaneous tissue) developed (Sreekumaran and Rajan

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1977). Skin changes in these kids are discussed in Chapter 2. When eight-month-old male goats were made hypothyroid with thiourea, plasma testosterone levels decreased to less than 12% of pretreatment levels (Gupta et al. 1991). Long-term feeding of Brachiaria mutica grass with high but sublethal nitrate concentration has resulted in abnormally small and firm thyroid glands and mild proliferation of the acinar epithelium (Prasad 1983). Naturally Occurring Dietary Goiter Enlargement of the thyroid gland is usually a nutritional disease. ETIOLOGY. There are two major mechanisms by which diet can cause development of goiters in goats: iodine deficiency and feeding of goitrogens. In addition, experimental cobalt deficiency (and thus vitamin B12 deficiency) has produced elevated thyroxine levels accompanied by marked hypertrophy and hyperplasia of the thyroid gland (Mgongo 1981); however, in a later study thyroid function was not markedly impaired by cobalt deficiency (Mburu et al. 1994). IODINE DEFICIENCY GOITER. ”Endemic” goiter in goats has generally been recognized in the past in the same regions where human goiter occurred. Soils are deficient in iodine or do not release it readily to plants and drinking water. Iodine-deficient regions include the Great Lakes, Great Plains, Rocky Mountains, and Pacific Coast regions of the United States (Lall 1952); Switzerland; parts of Great Britain (Wilson 1975); and the Himalayas (Raina and Pachauri 1984). The availability of iodized salt has decreased the prevalence of this type of goiter in both the United States and Western Europe. Goiter remains common in the Himalayas, where supplementation is not as available (Singh et al. 2002). Breeds of goats vary in sensitivity to iodine deficiency. The Boer goat, a rapidly growing meat breed from South Africa, seems to be especially susceptible. It is possible that selection for resistance to iodine deficiency would be selection for slow growth rate (van Jaarsveld et al. 1971). In the Himalayas, where caprine goiter was extensively studied, indigenous strains were apparently more resistant to iodine deficiency than were goats (Barbari or Alpine) purchased from outside regions (Rajkumar 1970). The Angora goat is apparently very susceptible to iodine deficiency (Kalkus 1920). GOITROGENS. Goitrogens are compounds that interfere with the uptake of dietary iodine or with its metabolism in the formation of thyroxine (Bath et al. 1979; Cheeke 1998). Thiocyanate is a goitrogen present in many species of brassicas, members of the Brassicaceae (Cruciferae) family. Increasing dietary iodine will overcome the inhibitory effects of thiocyanate on selective concentration of iodine by the thyroid. Goitrin (thio-

oxazolidone) is a thiouracil-type goitrogen found in the seeds of rape, kale, and other Brassica spp. that blocks hormone synthesis; its action cannot be overcome by feeding additional iodine. Thiourea is similar and also interferes with organic binding of iodine; it has been used to produce experimental hypothyroidism (Wilson 1975). Mimosine in Leucaena leucocephala is broken down metabolically to a goitrogen in ruminants (Hegarty et al. 1976; Prasad 1989) but this chemical can be detoxified by natural populations of rumen bacteria (Hammond 1995). See further discussion in Chapter 10. African pearl millet (Pennisetum typhoides) is goitrogenic for goats, although the toxin has not been identified (Abdel Gadir and Adam 1999). CLINICAL SIGNS AND LABORATORY FINDINGS. The normal thyroid gland is 0.20% of body weight (Kaneko 1997). In goitrous regions, unsupplemented adults have marked enlargement of the thyroid, which is sometimes the size of an orange (Kalkus 1920). The goats otherwise look healthy. Reproductive performance may be decreased (Kategile et al. 1978). Humoral and cell-mediated immune responses may be decreased (Singh et al. 2006). Affected kids have thyroid enlargement at birth (Figures 3.8 and 3.9), and enlargement of the kid’s pituitary gland has also been described (Ozmen and Haligur 2005). They may be stillborn or are very weak and die within a few hours. Increased blood flow to the thyroid may cause a palpable thrill. Most of these kids are hairless or covered with very fine hair, while some have a normal hair coat (Kalkus 1920; Love 1942; Paliwal and Sharma 1979). It has suggested that multiple fetuses in a litter are more apt to be affected with dietary goiter than a single fetus (Ozmen and Haligur 2005). In one outbreak in South African Angoras, believed to be caused by thiocyanate from heavily fertilized alfalfa pastures, kids were viable but abnormal from birth (Bath et al. 1979). They were short, blocky, obese, and inactive. The skull was broadened laterally and prognathia inferior was present in all cases. Goiters were easily palpated bilaterally. Mean thyroxine level for four goitrous goats was 3.1 μg/dl, whereas the mean of four normal goats was 5.9 μg/dl. Plasma cholesterol was five times higher (10.9 mmol/l versus 1.8 mmol/l) in goitrous than control goats. In another case report, does were fed on cabbages and the kids appeared normal except for goiters measuring as large as 7 cm by 4.5 cm (Lombard and Raby 1965). The largest goiters were associated with severe dyspnea and death, whereas less markedly affected kids grew poorly. A study from an iodine deficient area of India evaluated 252 congenitally goitrous kids born to 574 does with goiter. Clinical signs included thyroid gland hypertrophy and palpable thrill, enlarged joints,

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Figure 3.8. Congenital iodine deficiency goiter in a stillborn kid. (Courtesy of Dr. M.C. Smith.)

Figure 3.9. Goiters exposed in twin stillborn kids by reflecting the skin. (Courtesy of Dr. M.C. Smith.)

muscle contracture, an arched back and waddling gait, partial to complete alopecia, weakness, and lethargy. Hydrocephalus and prognathism were less common. Serum cholesterol was increased while T3 and T4 were decreased. The incidence of stillbirth in this study was 18% (Sing et al. 2003).

DIAGNOSIS. Major differentials for a diagnosis of goiter include encapsulated abscesses and wattle cysts, which are unlikely to be bilateral and in the exact location of the thyroid. Thymic enlargement is more difficult to distinguish because the thyroid glands are normally embedded in the thymus. The kid with an enlarged thymus grows rapidly, has a healthy hair coat, and is active. As long as trace mineralized salt is available and no known goitrogens are being fed, the continued good health of the growing kid remains the ultimate diagnostic test to rule out goiter. Biopsy is not necessary, although normal thyroids contain acini lined by low cuboidal epithelium and filled with colloid, as opposed to the tall columnar epithelium, papillary infolding, and minimal colloid of goitrous glands (Love 1942; Roy et al. 1964). A hyperplastic goiter is transformed into a colloid goiter when the diet is improved or the lower iodine needs of an older animal are met, resulting in a gland that is still enlarged but has much colloid in the acini. Iodine content of the goitrous thyroid gland is reduced. Subclinical goiter is diagnosed when the glands appear to be normal size but are histologically hyperplastic. TREATMENT AND PREVENTION. The actual dietary iodine requirement for goats, as discussed in Chapter 19, is 0.8 mg/kg dry matter for lactating females and 0.5 mg/ kg for the rest of the herd. Cruciferous plants increase the ration iodine requirement to approximately 2 mg/kg. Iodine deficiency goiter is treated or prevented by supplying iodine to the goat, especially the pregnant doe. This can easily be done with iodized salt, assuming that no iodine-free salt source is available for the goats to satisfy their salt requirements. In a report from India, biochemical and hormonal values normalized in goitrous kids when colloidal iodine (I2) was given orally at 0.1 mg/kg bodyweight for 100 days (Singh et al. 2003). Synthetic sodium thyroxine (0.2 mg/day orally to goats weighing 16 to 20 kg) also corrected many clinical signs of deficiency (Singh et al. 2006) but should not be necessary once the diet is corrected. In the classic experiments of Kalkus (1920), oral daily potassium iodide (2 grains, 130 mg) or weekly application of 1 ml of tincture of iodine to the back throughout gestation were both successful in preventing goiter. Iodine treatment during the preceding pregnancy sometimes was enough to permit production of another normal kid. Adult goats with iodine deficiency goiter showed a decrease in thyroid size after treatment (Kalkus 1920; Welch 1928). Congenital goiter caused by goitrogens is best avoided by not feeding the incriminated forages (especially brassicas) during pregnancy. Supplemental iodine can also be fed to the does (Heras et al. 1984).

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Hereditary Goiter Congenital goiter occurred spontaneously in an inbred strain of Dutch goats (mixed Saanen and dwarf goats). The trait was maintained and studied extensively as a model for thyroid defects in humans. PATHOGENESIS. The condition was inherited as an autosomal recessive trait (Kok et al. 1987). Thyroglobulin, the normal precursor of the thyroid hormones T3 and T4, was not produced in the goat that was homozygous for this trait. As a consequence, the normal feedback mechanisms were impaired and continuous thyrotropin secretion led to development of a goiter. The responsible mutation in the thyroglobulin gene has been characterized (Rivolta and Targovnik 2006). CLINICAL AND LABORATORY FINDINGS. Normal thyroids (both together) in this breed weighed 1 to 4 g, and goiters weighed 15 to 300 g. Plasma T3 levels (9 to 36 ng/dl) and T4 levels (less than 0.4 μg/dl) were substantially lower than normal goat T3 (124 to 151 ng/dl) and T4 (5.9 to 10.2 μg/dl) levels (de Vijlder et al. 1978). Histologically, the goitrous thyroid had hypertrophic and hyperplastic epithelium consistent with prolonged thyrotropin stimulation. Colloid was almost absent. In addition to having enlargement of the thyroids, goitrous kids were sluggish and grew poorly. The hair coat was rough and sparse. If thyroxine replacement was not provided, the hair coat eventually disappeared almost completely and the skin became thick and scaly (Rijnberk 1977). Euthyroidism could be achieved with these goats using iodide supplementation (1 mg I− per day orally). Other proteins were iodinated and then converted to T3 and T4 even though thyroglobulin still was not synthesized (van Voorthuizen et al. 1978). CONGENITAL GOITERS IN OTHER BREEDS. Congenital goiters of possibly hereditary etiology have also been found in Boer goats (van Jaarsveld 1971). Except for the enlargement of the thyroid glands (average 37 g compared with the normal average 2 g), the kids appeared normal. Histologically, there was hypertrophy of the thyroid epithelium with absence of colloid. Normal iodoproteins were present, but the thyroglobulin polymers tended to dissociate into subunits. Congenital goiters (average 43 g compared with a normal average of 9 g) have also been suspected to be hereditary in Shami dairy goats (Al-Ani et al. 1998). An autosomal recessive hereditary goiter in goats in Inner Mongolia was controlled by removing known carriers and identifying other carriers in the herd using a goat-homologous assay for thyrotropin (Mei and Chang 1996). Thymus Young kids, especially if well fed, sometimes develop bilaterally symmetric swellings in the upper neck in the region of the thyroid gland (Figure 3.10). The swellings may first become noticeable as early as

Figure 3.10. Enlarged thymus in the upper neck of a rapidly growing Nubian cross kid. (Courtesy of Dr. M.C. Smith.)

two weeks of age and regress spontaneously, often at about four months of age (Pritchard 1987) or somewhat later (Bertone and Smith 1985). The kid is otherwise healthy, with a good hair coat, and therefore is unlikely to be affected with severe iodine deficiency or goiter. Another subcutaneous swelling occurs at the thoracic inlet. Aspiration of either the cranial or caudal cervical masses, while not indicated, yields thymic tissue. The origin of the excessive thymic tissue might be remnants from embryologic development or accessory thymus; in any case, the glandular tissue involutes naturally and no treatment is needed. Owners should be warned of the potential for iodine toxicity if unnecessary supplements, such as kelp, are fed when no thyroid deficiency exists. Tumors of the thymus occur in adult goats, and their presence as a space-occupying lesion or incidental finding in the thorax is discussed in Chapter 9. Less commonly, remnants of the cervical portion of the thymus become neoplastic. Diagnosis is by examination of a biopsy or aspirate, and treatment by surgical excision. Thymic tissue may also be embedded within the thyroid gland of goats of any age (Roy et al. 1976), often in association with parathyroid tissue, but no clinical relevance has been reported for this histologic finding.

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Phlebitis Because the jugular veins are commonly used for venipuncture and administration of various medications, iatrogenic phlebitis may be expected to occur occasionally. Hematomas typically resolve quickly without treatment, whereas perivascular deposition of irritating drugs can lead to cellulitis or even abscessation. Conservative therapy, including application of hot compresses, is preferable to lancing a swelling so close to the jugular vein. Atlantal Bursitis Atlantal bursitis is a fairly specific but uncommon sign of caprine arthritis encephalitis virus infection. A fluctuant swelling is located underneath and extends on both sides of the ligamentum nuchae (Figure 3.11). The bursa often contains mineralized material, which can be demonstrated with a radiograph (Garry and Rings 1985). Histology shows hyperplasia of synovial cells and mononuclear cell infiltration (Gonzalez et al. 1987). An abscess can develop if aspiration is attempted. The supraspinous bursa may be similarly involved, as may be other bursae over the carpus, olecranon, or tuber ischii. Usually at least some degree of lameness is present by the time the atlantal bursa becomes noticeably distended. Sternal Abscesses and Hygromas Sternal abscesses were detected in seventy-two goats in a large antibody-producing herd over a sixteen-year period (Gezon et al. 1991). These abscesses were 3 to 15 cm in diameter and usually involved skin and subcutaneous tissues, but rarely invaded muscle or bone. Two of the goats, however, had osteomyelitis of the sternum. Bruises and abrasions of an area com-

monly exposed to manure were proposed as an explanation of the occurrence of the abscesses. Antibiotic therapy had little effect on the condition. The authors did not adequately report culture results, and thus no conclusions can be drawn from this study concerning bacteria present in unbroken sternal abscesses. Sternal abscesses are, in the authors’ experience, most common in goats afflicted with severe lameness, such as from arthritis associated with caprine arthritis encephalitis virus infection. Two hypotheses come to mind to explain this association. First, the lame goat spends more time in sternal recumbency and therefore may develop a hygroma or decubital sore. Second, the caprine arthritis encephalitis virus-induced arthritis might involve joints between sternebrae, with secondary bacterial infection. Successful treatment of these abscesses often requires surgical debridement. Radiographic evaluation for osteomyelitis or enlargement (and probable infection) of lymph nodes within the thoracic cavity are helpful in offering a prognosis and determining the extent of surgical debridement required. Goats that are markedly lame and emaciated or have extension of infection into the thorax will probably benefit little from treatment of a sternal abscess. Warbles Larvae of Przhevalskiana silenus, a warble fly that migrates to the back region of goats in Mediterranean countries and Asia, are accompanied by localized inflammatory reaction and granulation tissue in the subcutaneous tissue. This parasite is discussed in Chapter 2. Although cattle warble fly larvae (Hypoderma spp.) could potentially invade goats, natural occurrence has not been documented and experimental infections with Hypoderma lineatum larvae did not progress to the development of subcutaneous warbles (Colwell and Otranto 2006). Tapeworm Cysts

Figure 3.11. Distension of the atlantal bursa in a goat with clinical CAE arthritis. (Courtesy of Dr. M.C. Smith.)

The intermediate form of the dog tapeworm Taenia multiceps (previously called Multiceps multiceps or M. gaigeri) forms cysts within the central nervous system (CNS) of sheep and goats, but also outside the CNS of goats, especially in muscle and subcutaneously (Verster 1969). Scolices are arranged in clusters and there are no internal or external daughter cysts. These cysts have been reported as the cause of large (approximately 15 cm in diameter) subcutaneous swellings distributed over the limbs and body of goats in the Sudan (Ramadan et al. 1973; Hago and Abu-Samra 1980) and India (Shastri et al. 1985). The cysts are fluctuating, cool, and covered with hairless skin. Depending on the cyst location, there may be interference with locomotion, feeding, or function of internal organs. Head shaking is commonly observed when cysts are near the base of the ear.

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Several methods of treatment have been successful, including excision of the cyst, lancing the cyst and packing the cavity with gauze soaked in iodine, or aspirating all the fluid and infusing 0.5 to 1 ml of Lugol’s iodine into the collapsed cyst (Nooruddin et al. 1996). When a herd outbreak occurs, as in a reported case involving forty-seven of 169 Black Bengal goats, emphasis should obviously be put on treating dogs for tapeworms and destroying the carcasses of dead goats to prevent consumption by the dogs or wild canids (Patro et al. 1997).

SWELLINGS INVOLVING THE ABDOMEN AND ESCUTCHEON Alteration in the abdominal silhouette is discussed in detail in Chapter 10. Umbilical Hernia Umbilical hernia caused by the incomplete closure of the umbilical ring (in the absence of omphalitis) is rare in goats. A genetic predisposition has not been identified in this species (Hámori 1983). Nevertheless, prudence dictates that males that will be used extensively for breeding should be free of all recognizable congenital defects. Goats with a swelling originating from the umbilical region should be examined by palpation while standing, and if necessary, in lateral recumbency. If the swelling is easily reduced with no tenderness or thickened stalk, then it is likely that it is a hernia unaccompanied by an abscess. In young female goats, wrapping the abdomen for two to four weeks with adhesive elastic tape may permit closure of the hernia ring to occur. If the defect is large, an internal abscess is suspected, or the patient is male, surgical repair is the preferred therapy. The goat is placed in dorsal recumbency and standard techniques appropriate for herniorrhaphy in calves are employed. Prosthetic mesh may be required to close large defects in the body wall (Fubini and Campbell 1983). An alternative nonsurgical repair has been described using an elastrator castration band. The animal is lightly sedated and placed in dorsal recumbency. With all of the contents of the hernia sac replaced into the abdomen, two metal pins such as diaper pins are inserted through the skin on each side of the sac, so that they will sit close to the abdominal wall. An elastrator band is then placed around the hernial sac, between the pins and the body wall, where it causes sloughing of the skin and healing of the defect within two weeks (Navarre and Pugh 2002). Tetanus prophylaxis is imperative. Umbilical Abscess If palpation of an umbilical swelling reveals warmth, tenderness, or just an irreducible fluctuance, diagnos-

tic aspiration is indicated. Omphalitis may result in abscessation of remnants of umbilical arteries, the umbilical vein, or the urachus. Ultrasonography may be useful for evaluation of the extent of internal involvement of an umbilical abscess. External abscesses are drained and systemic antibiotics are administered for one week or longer. If evidence of infection or concurrent hernia persists, surgical debridement and herniorrhaphy are recommended. Abdominal or Flank Hernia The abdominal wall of a goat is relatively thin. Muscle tearing and separation often occur from blunt trauma during fighting, shearing, or crowding through narrow doorways. Diagnosis of a unilateral flank hernia is usually obvious, although it is important to determine if a pregnant uterus is trapped in a subcutaneous location. When the hernia or stretching of the body wall is bilateral (as from doorways) it should be distinguished from pregnancy, hydrometra, obesity, or ascites by careful physical examination. Small hernias may be surgically repaired, while hernias large enough to impede parturition are usually an indication for culling in a commercial herd. Tranquilization with xylazine and local anesthesia using a ring block of lidocaine (not to exceed 10 mg/kg) has been used for repair of abdominal hernias in goats (AlSobayil and Ahmed 2007). Either absorbable or nonabsorbable suture is satisfactory, with nonabsorbable (the authors used silk) favored in older animals or those with more longstanding hernias. Ventral Hernia Occasionally, trauma or extreme abdominal distention leads to rupture of the ventral abdominal muscles caudal to the umbilicus, as described in sheep (Arthur et al. 1989). This results in edematous swelling of the abdominal wall and dropping of the udder. Successful surgical repair has been reported in a goat (Misk et al. 1986). The late pregnant uterus can become trapped in the hernia in a subcutaneous location, making vaginal delivery difficult (Horenstein and Elias 1987). Successful surgical correction of such a “metrocele” at four months gestation has been reported (Radhakrishnan et al. 1993). Ventral Edema of Angoras Angora goats in South Africa, the United States, New Zealand, and England have developed severe edematous swelling (“swelling disease” or “water belly”) of the ventral abdomen and chest and sometimes the limbs and submandibular region after shearing or other stress (Mitchell et al. 1983; Byrne 1994a, 1994b; Thompson 1994). As many as 15% of the herd may be affected. The swelling consists of clear, copious, nonclotting fluid and disappears spontaneously in a

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few days. Possible etiologies discussed in the literature include hypoproteinemia and change in capillary permeability, stress (via increased aldosterone secretion and sodium retention), and vitamin E deficiency. Research attempting to recreate the condition with parasitic infections or modify it with increased dietary protein has been inconclusive, but in general the smaller goats with lower plasma total protein concentrations are at higher risk (Snyman and Snyman 2005). Hypoalbuminemia due to parasitism or paratuberculosis and edema caused by congestive heart failure must be ruled out in individual animals that do not recover rapidly. If sudden deaths occur in the herd, vitamin E status should be investigated (Byrne 1994a). Otherwise, no treatment is indicated except provision of feed and shelter for newly shorn animals. Urethral Rupture Bucks and wethers with urolithiasis may develop a ventral swelling (water belly) if the urethra ruptures and urine leaks into subcutaneous tissues. The swelling is edematous and cool; aspiration yields a watery fluid that may have an ammoniacal odor when heated. The fluid can be reabsorbed if the obstruction to normal urine flow is relieved. Localized skin sloughing may occur. Urolithiasis and its treatment are discussed in detail in Chapter 12. Gangrenous Mastitis The skin of the ventral abdomen anterior to the udder may become swollen and edematous because of vascular thrombosis in goats with gangrenous mastitis. Initially the swelling is cool; necrosis and sloughing may eventually occur. Gangrenous mastitis is discussed in Chapter 14. Ectopic Mammary Gland The embryonic mammary line of mammals extends from the pectoral region to the vulva. Although female goats usually develop only two functional glands in an inguinal location, milk-secreting tissue is occasionally located bilaterally in the lips of the vulva (Lesbouyries and Drieux 1945; Kulkarni and Marudwar 1972; Ramadan and El Hassan 1975; Smith 1986). As parturition approaches, the vulva enlarges, as does the udder. This vulvar swelling is firm and lobular (Figure 3.12), is separated from the skin, and does not subside promptly after parturition as physiologic edema would. Instead, the vulva remains distended for as long as three months, but eventually subsides as the glandular tissue becomes atrophied from the backpressure of entrapped milk. The condition is merely a curiosity but can be confirmed by aspiration of a whitish fluid containing fat globules. The bilaterally symmetrical nature of the swelling also helps to dif-

Fig. 3.12. Ectopic mammary gland distending the vulva of a mature Saanen doe one day after parturition. The doe also has a retained placenta. (Courtesy of Dr. M.C. Smith.)

ferentiate ectopic mammary gland from an adenocarcinoma or other neoplasm (see Chapter 2). Mammary gland development in the buck (gynecomastia) is discussed in Chapter 13.

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Singh, V.P. and Murty, D.K.: An outbreak of Dermatophilus congolensis infection in goats. Indian Vet. J., 55:674–676, 1978. Smith, M.C.: Neoplasms of the goat’s reproductive tract. In: Current Therapy in Theriogenology 2. D.A. Morrow, ed. Philadelphia, W.B. Saunders Co., pp. 628–629, 1986. Snyman, M.A. and Snyman, A.E.: The possible role of Ostertagia circumcincta, coccidiosis and dietary protein level in the development of swelling disease in Angora goat kids. J. S. Afr. Vet. Assoc., 76:63–68, 2005. Sreekumaran, T. and Rajan, A.L.: Pathology of the skin in experimental hypothyroidism in goats. Kerala J. Vet. Sci., 8:227–234, 1977. Sreekumaran, T. and Rajan, A.: Clinicopathological studies in experimental hypothyroidism in goats. Vet. Pathol., 15:549–555, 1978. Sting, R., Steng, G., and Spengler, D.: Serological studies on C. pseudotuberculosis infections in goats using ELISA. J. Vet. Med. B., 45:209–216, 1998. Sutmöller, P., Kraneveld, F.C., and van der Schaaf, A.: Melioidosis (pseudomalleus) in sheep, goats, and pigs on Aruba (Netherland Antilles). J. Am. Vet. Med. Assoc., 130:415–417, 1957. Sweeney, R.W., et al.: Pharmacokinetics of rifampin in calves and adult sheep. J. Vet. Pharmacol. Ther., 11:413–416, 1988. Tadjalli, M., Dehghani, S.N., and Ghadiri, M.: Sialography of the goat parotid, mandibular and sublingual salivary glands. Small Rumin. Res., 44:179–185, 2002. Tanwar, R.K. and Saxena, A.K.: Radiographic detection of foreign bodies. Vet. Med., 79:1195–1197, 1984. Tanwar, R.K., et al.: Subcutaneous emphysema in goats. Mod. Vet. Pract., 64:670, 1983. Thomas, A.D. and Forbes-Faulkner, J.C.: Persistence of Pseudomonas pseudomallei in soil. Aust. Vet. J., 57:535–536, 1981. Thomas, A.D., et al.: Clinical and pathological observations on goats experimentally infected with Pseudomonas pseudomallei. Aust. Vet. J., 65:43–46, 1988a. Thomas, A.D., et al.: Evaluation of four serological tests for the diagnosis of caprine melioidosis. Aust. Vet. J., 65:261– 264, 1988b. Thompson, K.G.: Ventral oedema in exotic Angora goats. N.Z. Vet. J., 42:35–37, 1994. Turner, A.S. and McIlwraith, C.W.: Techniques in Large Animal Surgery. 2nd Ed. Philadelphia, Lea and Febiger, 1989. Van der Lugt, J.J., and Henton, M.M.: Melioidosis in a goat. J. S. Afr. Vet. Assoc., 66:71–73, 1995. Van Jaarsveld, P., et al.: Congenital goitre in South African Boer goats. J. S. Afr. Vet. Med. Assoc., 42:295–303, 1971. Van Tonder, E.M.: Notes on some disease problems in Angora goats in South Africa. Vet. Med. Rev., 1/2:109–138, 1975. Van Voorthuizen, W.F., et al.: Euthyroidism via iodide supplementation in hereditary congenital goiter with thyroglobulin deficiency. Endocrinology, 103:2105–2111, 1978. Verster, A.: A taxonomic revision of the genus Taenia Linnaeus, 1758 s. str. Onderstepoort J. Vet. Res., 36:3–58, 1969. Washburn, K.E., et al.: Comparison of core needle biopsy and fine-needle aspiration of enlarged peripheral lymph nodes

84 Goat Medicine for antemortem diagnosis of enzootic bovine lymphosarcoma in cattle. J. Am. Vet. Med. Assoc., 230:228–232, 2007. Welch, H.: Goiter in farm animals. Univ. Montana Agric. Exper. Stat. Bull., 214, June 1928. Wentzel, D., Viljoen, K.S., and Botha, L.J.J.: Seasonal variation in adrenal and thyroid function of Angora goats. Agroanimalia, 11:1–3, 1979. Wiggs, R.B. and Lobprise, H.B.: Acute and chronic alveolitis/osteomyelitis (“lumpy jaw”) in small exotic ruminants. J. Vet. Dent., 11:106–109, 1994. Williams, C.S.F.: Differential diagnosis of caseous lymphadenitis in the goat. Vet. Med. Small Anim. Clin.,

75:1165–1169, 1980. Reprinted in Dairy Goat J., 60:836–840, 1982. Williamson, L.H.: Caseous lymphadenitis in small ruminants. Vet. Clin. North Am. Food Anim. Pract., 17:359–371, 2001. Wilson, J.G.: Hypothyroidism in ruminants with special reference to foetal goitre. Vet. Rec., 97:161–164, 1975. Yates, N.G., Hoffmann, D., and Seripto, S.: Mandibular osteodystrophy fibrosa in Indonesian goats fed leucaena. Trop. Anim. Health Prod., 19:121–126, 1987. Zaki, M.M.: The application of a new technique for diagnosing Corynebacterium ovis infection. Res. Vet. Sci., 9:489–493, 1968.

4 Musculoskeletal System Background Information of Clinical Importance 85 Anatomy and Physiology 85 Clinical Pathology 88 Diagnostic Procedures 91 Diagnosis of Musculoskeletal Disease by Presenting Signs 92 Abnormally Appearing or Sore Feet 92 Swelling Around the Joints 94 Stiff, Painful, or Abnormal Gait 94 Failure to Extend a Limb or Limbs 94 Non-weightbearing on a Single Limb 95 Bowed Limbs 95 Conditions Restricted to a Fore Limb 95 Conditions Restricted to a Hind Limb 95 Weakness and Recumbency 96 Specific Diseases of Musculoskeletal System 96 Viral Diseases 96 Caprine Arthritis Encephalitis (CAE) 96 Foot and Mouth Disease 106 Akabane Disease 112 Bacterial Diseases 114 Mycoplasma Arthritis 114 Bacterial Polyarthritis 121 Osteomyelitis 122 Lyme Disease 123 Clostridial Myositis and Myonecrosis 124 Foot Scald, Foot Rot, and Foot Abscesses 126

Maintenance of musculoskeletal health is critical to the general well being of goats. Under extensive management systems, normal ambulation is essential for efficient and adequate food gathering and flight from predators. Agility and limb strength are especially important in hilly, rocky environments and during periods of food scarcity when goats will actually climb into trees to obtain feed. Successful breeding performance for male goats depends on sturdy, pain-free hind limbs for efficient mounting of does. For milking does, incorrect hind limb conformation and overgrown hooves can adversely affect udder health, and skeletal conformation is considered an important trait in linear appraisal systems for evaluating dairy goats. This chapter presents clinically important background information relating to the musculoskeletal system, the differential diagnosis of musculoskeletal diseases on the basis of presenting sign, and detailed Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Parasitic Diseases 130 Cestodiasis 130 Besnoitiosis 130 Sarcocystosis 131 Nutritional and Metabolic Diseases 131 Nutritional Muscular Dystrophy 131 Rickets 135 Epiphysitis 136 Bentleg or Bowie 137 Fibrous Osteodystrophy (Osteodystrophia Fibrosa) 137 Osteopetrosis 138 Laminitis 139 Zinc Deficiency 140 Toxicological diseases 140 Hypervitaminosis D 140 Fluorosis 141 Chronic Selenium Poisoning 144 Plants Toxic to the Musculoskeletal System 145 Lupinosis 146 Inherited and Congenital Diseases 146 Myotonia Congenita 146 Various Congenital Skeletal Abnormalities 147 Traumatic Diseases 147 Predation 147 Fractures 149 Neoplastic Diseases 150 References 150

discussion of the primary diseases affecting the muscles, bones, and joints of goats. The reader is referred to Chapter 19 for additional background information on requirements and use of specific nutrients affecting bone and muscle health.

BACKGROUND INFORMATION OF CLINICAL IMPORTANCE Anatomy and Physiology A detailed review of the musculoskeletal anatomy of the goat is beyond the scope of this text and the information is available from other sources (Chatelain 1987; Constantinescu 2001; Popesko 2008). A representation of the caprine skeleton is given in Figure 4.1 and topographic muscular anatomy of the goat in Figure 4.2. 85

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Figure 4.1. The caprine skeleton. 1. maxilla, 2. mandible, 3. atlas, 4. axis, 5. fifth cervical vertebra, 6. sixth thoracic vertebra, 7. thirteenth thoracic vertebra, 8. sixth lumbar vertebra, 9. sacrum, 10. coccygeal vertebrae, 11. cartilage of scapula, 12. first rib, 13. thirteenth rib, 14. body of sternum, 15. xiphoid cartilage, 16. scapula, 17. humerus, 18. ulna, 19. radius, 20. carpal bones, 21. third and fourth metacarpal bone, 22. bones of digits of thoracic appendage, 23. os coxae, 24. femur, 25. patella, 26. tibia, 27. tarsal bones, 28. third and fourth metatarsal bone, 29. bones of digits of pelvic appendage. (Reproduced with permission from Popesko P.: Atlas of Topographical Anatomy of Domestic Animals, new revised English edition, Vydavatelstvo Priroda, Bratislava, 2008, www.priroda.sk.)

Normal Skeletal Variations Goats commonly have numerical variation in vertebrae. The normal vertebral formula is seven cervical, thirteen thoracic, six lumbar, five sacral, and seven to twelve coccygeal vertebrae. One survey of 185 goats revealed that 24% had numerical variation of vertebrae or the presence of structurally transitional vertebrae (Simoens et al. 1983). Common variations include twelve thoracic, five lumbar, and four or six sacral vertebrae. These variations are rarely, if ever, associated with clinical disease. An extra sesamoid bone is infrequently found at the lateral head of the gastrocnemius muscle (Rajtova 1974). Floating ribs, with no connection to the costal arch, also occur infrequently (Hentschke 1980). Bone Growth There are several reports on epiphyseal closure times in growing goats (Dhingra and Tyagi 1970; Rajtova 1974; Ho 1975; Dhingra et al. 1978). The findings are widely disparate for numerous epiphyses; the reasons for these disparities are unclear. In the most recent study in Korean native goats, the distal humeral

epiphysis fused at eight to twelve months; proximal radial epiphysis and distal tibial epiphysis fused at one year; and proximal and distal epiphyses of ulna and femur, proximal epiphyses of humerus and tibia, and distal epiphysis of radius fused at one year or later (Choi et al. 2006). Sexual dimorphism occurs in caprine bone growth. Males have longer and wider bones and later closure of epiphyses than females (Rajtova 1974). The Parathyroid Glands The parathyroid glands play an important role in the development and maintenance of normal bone through the action of parathyroid hormone on calcium and phosphorus metabolism (Hove 1981; Care and Hove 1982). Histologic evaluation of the glands can be a valuable aid in the diagnosis of metabolic bone disease. These glands may be difficult to locate in the goat because of small size and variable relationship to other tissues. There are usually two pairs, though accessory parathyroid tissue can occur. The anterior pair are usually located deep in the anterior portion of the neck at the bifurcation of the

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Figure 4.2. Topographic anatomy of the superficial caprine musculature. 1. masseter muscle, 2. brachiocephalic muscle, 3. cleido-occipital muscle, 4. sternomandibular muscle, 5. cleidobrachial muscle, 6. cervical part of trapezius muscle, 7. thoracic part of trapezius muscle, 8. aponeurosis of deltoid muscle, 9. deltoid muscle, 10. tensor fasciae antebrachii muscle, 11. omotransverse muscle, 12. long head of triceps brachii muscle, 13. lateral head of triceps brachii muscle, 14. superficial pectoral muscles, 15. latissimus dorsi muscle, 16. thoracic ventral serratus muscle, 17. deep pectoral muscle, 18. extensor carpi radialis muscle, 19. extensor carpi ulnaris muscle, 20. caudal dorsal serratus muscle, 21. thoracolumbar fascia, 22. internal oblique abdominal muscle, 23. external oblique abdominal muscle, 24. aponeurosis of oblique muscles of abdomen, 25. tuber coxae, 26. middle gluteal muscle, 27. tensor fasciae latae muscle, 28. gluteobiceps muscle (28–superficial gluteal muscle, 28’-biceps femoris muscle), 29. semitendinosus muscle, 30. peroneus longus muscle. (Reproduced with permission from Popesko P.: Atlas of Topographical Anatomy of Domestic Animals, new revised English edition, Vydavatelstvo Priroda, Bratislava, 2008, www.priroda.sk.)

common carotid artery. In the young goat, thymus is present at this site and the parathyroid gland may be recognized as a small reddish brown mass about 5 mm in diameter at the cranial pole of the thymus. Thymic tissue is atrophied in older goats, and the external parathyroid gland may be found caudal to the bifurcation of the common carotid artery. The posterior pair are usually located within the paired thyroid glands, most often in the middle portion on the medial aspect of the thyroid. The parathyroid tissue may be isolated in a distinct connective tissue capsule or mingled with thyroid tissue. Conformation There is increasing application of linear appraisal systems to generate sire summary information for the

genetic improvement of dairy goats in breeding programs. The linear appraisal system is modeled after that used in dairy cattle and attempts to define a structural conformation consistent with functional durability as well as reproductive and productive efficiency. Type traits related to conformation that are included in linear appraisals are stature, rump angle, rump width, and rear legs (Wiggans and Hubbard 2001). Skeletal conformation is also a significant component of dairy goat judging. Feet and legs are distinct structural categories subject to scoring. Recognized defects that reduce an animal’s score include excessive spreading of the toes, shallow heels, turning out of the front feet or legs, rolled or turned-over claws, weak pasterns, winged-out shoulders or elbows, bowed or crooked forelimbs, straight stifles, rear limbs too

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close together (impinging on udder), turned-in hocks, and enlarged joints (Considine and Trimberger 1978). The selection and judging of meat goats also includes skeletal and conformational criteria (Martinez et al. 1991). Clinical Pathology The most commonly used clinical chemical parameters for assessment of bone in health and disease are serum alkaline phosphatase (AP), calcium, and inorganic phosphorus. Variations in these parameters associated with different metabolic and nutritional bone diseases of goats are summarized in Table 4.1. Serum vitamin D and magnesium levels are less frequently evaluated. For evidence of muscle damage, serum activities of creatine kinase (CK), aspartate aminotransferase (AST), and lactate dehydrogenase are most commonly measured. Reported values for these parameters in goats are given in Table 4.2. As discussed later, variation may occur with regard to age, breed, sex, and stage of production or pregnancy status. Alkaline Phosphatase In goats, as in other species, serum AP is higher in young animals compared with adults due to AP activity associated with the increased osteoblast function of growing bone (Castro et al. 1977; Sugano et al. 1980; Bogin et al. 1981). In healthy adults, most of the serum AP present is derived from liver, particularly bile duct epithelium. Tissue enzyme profiles in goats demonstrate that AP activity is fifty to one hundred times greater in kidney than in liver (Kramer and Carthew 1985). However, in renal disease, AP from tubular epithelium is released into the urine rather than the blood. There are now immunoassays avail-

able for measurement of bone-specific alkaline phosphatase that were developed for use in humans, validated in sheep, and successfully applied to goats (Liesgang et al. 2006). There is considerable variation in serum AP activity between individual goats even within the same age group, resulting in a very wide range of reported normal values. In any individual healthy goat, however, serum AP levels usually remain constant (Kramer and Carthew 1985). More recently, measuring bone-specific alkaline phosphatase in Saanen does, it was shown that serum concentrations dropped progressively through pregnancy and reached their lowest point in the week following parturition. This reflects remodeling and calcium release from bone in response to skeletal demands of the fetus and early lactation (Liesegang et al. 2006, 2007). There is evidence that high and low AP enzyme levels in goats are heritable with the high level being genetically dominant (Lode 1970). Therefore, detection of a single high serum AP value in an individual goat may be difficult to interpret clinically. Increases in serum AP on serial samples within the same goat are a more reliable indication of bone or liver disease. Calcium The reported range of normal serum calcium in goats is fairly narrow. Nevertheless, within that range, significant differences have been noted with regard to age, breed, pregnancy status, and lactation status. Young goats tend to have higher serum calcium than mature goats (Bogin et al. 1981; Ridoux et al. 1981). In a French study, Saanen goats had higher mean serum calcium levels than Alpine goats (Ridoux et al. 1981). Mean serum calcium was significantly higher in black

Table 4.1. Clinical pathological changes associated with metabolic bone and muscle diseases in goats. Disease

Serum alkaline phosphatase

Serum calcium

Serum phosphorus

Other changes

Rickets

Increased

Decreased

Decreased

Epiphysitis

Normal

Normal

Normal

Fibrous osteodystrophy Chronic fluorosis

Increased

Normal or decreased

Normal or increased

Normal or increased

Normal or decreased

Normal or increased

Enzootic calcinosis

Increased

Increased

Increased

Hypervitaminosis D

Highly variable

Increased

Increased

Decreased serum vitamin D levels may also occur Excessive calcium in ration likely Excessive phosphorus in ration likely Increased fluoride levels in bone Calcification of soft tissues Increased serum vitamin D3 levels

Table 4.2. Some normal values for bone- and muscle-related enzymes and electrolytes in goat serum. Parameter

Unit

Goat description

Mean

± SD

Alkaline phosphatase

IU/l IU/l IU/l IU/l mU/ml mU/ml IU/l IU/l

F, pygmy, 800

3 250

25

4 4 8

LD50 = 100 LD50 = 25 LD50 > 160

Traditional test methods determine the change of pH that occurs when acetylcholinesterase hydrolyses acetylcholine or a substitute ester under controlled conditions. The normal range of delta pH for caprine whole blood acetylcholinesterase activity is 0.04 to 0.24, with a mean of 0.14 (Osweiler et al. 1984). In cases of toxicity, delta pH is frequently zero. Titrimetric methods, which do not require sample dilution, report acetylcholinesterase activity as the μmol of substrate hydrolyzed/minute/ml of whole blood or plasma. Normal values in goats using acetylcholine iodide as a substrate have been reported in the range of 4.20 to 5.60 μmol/minute/ml of whole blood and 0.60 to 1 μmol/minute/ml in plasma. Activity was reduced to levels of 20% to 50% of normal after oral administration of toxic doses of diazinon, phosmet, phosphamidon, or trichlorfon, with reported activity ranging

from 0.90 to 2.50 μmol/minute/ml in whole blood and 0.27 to 0.32 μmol/minute/ml in plasma (Abdelsalam 1987). Dialkyl phosphates are hydrolytic breakdown products of the phosphate moieties of organophosphate insecticides. Detection of dialkyl phosphates in the urine of goats proved to be a reliable indicator of exposure to diazinon over a range of challenge doses (Mount 1984). The test was more sensitive than measurement of blood cholinesterase activity in goats not showing clinical signs of toxicity. There are no specific necropsy findings in organophosphate or carbamate poisoning. Chemical analysis of tissues is often unrewarding because organophosphate and carbamate insecticides are rapidly metabolized. Analysis of stomach or rumen content, suspected feeds, or other formulations for insecticide content is preferred.

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Diagnosis Diagnosis is based on the characteristic signs of acute toxicity in conjunction with documentation of decreased or absent acetylcholinesterase activity. In the absence of laboratory support, a favorable clinical response to atropine or oxime therapy supports the diagnosis. Other acute poisonings, such as cyanide, nitrate, and urea toxicity, and anaphylactic reactions must be considered in the differential diagnosis. The pyrethroid insecticide fenvalerate has been shown to produce clinical signs suggestive of organophosphate toxicity when administered orally to Nubian goats at doses more than 112.5 mg/kg (Mohamed and Adam 1990). Treatment and Control Treatment can be successful, especially with early intervention. The treatment of choice to counteract signs of toxicity is atropine sulfate given at a dose of 0.6 to 1 mg/kg bw. One-fourth to one-third the total dose should be given intravenously and the remainder subcutaneously or intramuscularly. The higher end of the dose range can be used in severe cases. Repeated dosing may be necessary every four to five hours for as long as two days in severe cases, but dosage should be cut back when possible to avoid serious bloat. Oximes, such as trimedoxime bromide, 2-pyridine aldoxime methiodide (2-PAM), and pralidoxime chloride, free acetylcholinesterase from organophosphate, but not from carbamate complexes. They are particularly useful in combination with atropine for the treatment of coumaphos, ronnel, dimethoate, and crufomate toxicity, where atropine alone is not always effective (Osweiler et al. 1984). The use of these drugs in goats is not reported. In other ruminants, recommended doses are as follows; 2-PAM, 50 to 100 mg/kg bw; trimedoxime bromide, 10 to 20 mg/kg bw; and pralidoxime chloride, 20 mg/kg bw intravenously. When poisoning is by the oral route, oral administration of 1 g/kg bw activated charcoal per adult goat by orogastric tube may help to reduce the additional uptake of insecticide. When exposure is dermal, washing animals with soap and water helps to reduce additional absorption. Handlers should wear masks and rubber gloves. Control of these toxicities is difficult because most outbreaks involve accidental exposure. Certainly these chemicals should be treated with respect and used only according to directions. They should be stored securely where animal contact is impossible. Chlorinated Hydrocarbons Etiology and Epidemiology These insecticide compounds, also known as organochlorines, have been used widely in agriculture

for treatment of soils, water supplies, crops, seeds, and livestock. Methoxychlor, lindane, DDT, aldrin, dieldrin, chlordane, and toxaphene are common examples. Use of these insecticides directly on livestock is increasingly restricted due to environmental and public health concerns. Nevertheless, accidental exposures or inappropriate use still lead to toxicities in livestock, including goats. Information on toxic doses of various chlorinated hydrocarbons for goats is given in Table 5.5. Because goats are used for both meat and milk production, the potential for relay toxicity to humans from consumption of goat products is similar to cattle. These compounds are noted for persistence in fatty tissues over long periods. Residue levels in goat milk and tissues for various chlorinated hydrocarbons have been reported (Cho et al. 1976). Pathogenesis The pathogenesis of toxicity for these compounds is not completely known and may be different for each. At least for chlorophenothane, the compound acts on axonal membranes to prolong the depolarized state by interfering with sodium influx and potassium efflux. Poisoning can occur by single large-dose exposure or chronic lower-dose exposure due to the ability of these insecticides to accumulate in tissues. Absorption of these chemicals can occur through the skin, or by oral ingestion, aspiration, or inhalation. Neurologic signs in all cases are the usual clinical manifestation. Clinical Findings Clinical signs are similar in all species. Hypersensitivity, apprehension, and/or aggressiveness are frequent early signs followed by fasciculation of muscles, especially in the head and neck, that extend to muscular spasms over the entire body. Snapping of the eyelids and continuous chewing or teeth grinding are common, sometimes with excessive salivation. Moderate bloating may occur. Loss of coordination with staggering gait, aimless wandering, or circling may be observed. Severe and prolonged convulsions frequently develop. It is not unusual for animals to have a high fever due to seizure activity. Though animals may die during convulsions, death is usually preceded by terminal coma. The severity of signs is to some extent dose dependent. Experimental poisoning with aldrin at a daily oral dose of 2.5 mg/kg bw led to clinical signs of depression, anorexia, teeth grinding, salivation, staggering gait, and hypersensitivity in one goat after eighteen days of dosing but no signs of toxicity in three others (Singh et al. 1985). Goats given daily aldrin orally at a dose of 20 mg/kg showed signs of hyperexcitability, incoordination of movement, muscle tremors, and convulsions by the ninth day of dosing, and died one to three days later (Omer and Awad Elkarim 1981).

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Clinical Pathology and Necropsy Clinicopathologic data are generally not helpful in the diagnosis before death. There are no specific necropsy findings, although pulmonary congestion and ecchymotic hemorrhages of the heart and other serosal surfaces may be observed. When there have been severe prolonged convulsions with fever, the intestines may have a blanched or cooked appearance. Diagnosis Presumptive diagnosis depends on a history of exposure to chlorinated hydrocarbons followed by the development of typical clinical signs. Definitive diagnosis depends on identification of the offending agent by laboratory analysis of hair samples, rumen content, fat biopsies, or milk samples antemortem or in tissue samples post mortem, especially liver, brain, and fat. Concentrations of the various chlorinated hydrocarbons considered diagnostic of toxicity in goat tissue are not well documented. Analyses are complex and costly so there should be some notion of the specific chemical being searched for. Treatment and Control Therapy is primarily supportive. When topical poisoning is involved, animals should be washed thoroughly with soap and water. Handlers should wear masks and rubber gloves. In cases of ingestion, gastric lavage may be performed or activated charcoal given at a dose of 1 g/kg bw per adult goat as soon as possible after exposure. Seizures may need to be controlled by use of long-acting barbiturates. Daily oral dosing of recovered animals with small volumes of mineral oil may help to clear chlorinated hydrocarbons from the intestinal tract but will have little or no effect in mobilizing the agents in tissue. Specific guidelines for the safety of meat and milk products from goats recovered from poisoning are not available. Because of the potential harmful effects in humans, the consumption of meat or milk from these recovered animals should be discouraged. Control essentially involves client education concerning the danger, proper usage, and safe storage of chlorinated hydrocarbons. Miscellaneous Organic Chemical Toxicities Levamisole, a widely used caprine anthelmintic, is one of the most common potential causes of neurotoxicity in goats. When overdosed, it can produce a clinical syndrome very similar to nicotine poisoning with signs including anxiety, hyperesthesia, increased urination and defecation, muscle tremors, staggering gait, and convulsions. More information on levamisole use and toxicity in goats is given in Chapter 10. Urea toxicity has been reported in goats. The syndrome is characterized by abdominal pain, bloat,

dyspnea, and frothy salivation; neurologic signs include ataxia, tremors, hyperesthesia, and struggling. The condition is discussed in detail in Chapter 19. Both cyanide and nitrate poisoning can produce signs of nervous dysfunction including excitement, muscle tremors, staggering gait, and dilated pupils secondary to systemic anoxia. These conditions are discussed in detail in Chapter 9. Diesel fuel poisoning has been reported in goats when the animals drank from a small pond containing fuel from an overturned tank truck (Toofanian et al. 1979). Goats drank the tainted water readily. Clinical signs developed within hours and included anorexia, depression, diarrhea, dyspnea, and a mucopurulent nasal discharge. The breath and the urine smelled strongly of diesel fuel. Affected goats progressively worsened; developed neurologic signs including incoordination, tremors, head pressing, aimless wandering, pica, abnormal vocalization, and recumbency; and died, presumably due to respiratory compromise. Nitrofurans are a class of antibacterials that were formerly in common use for control of enteric infections in young calves and pigs. Due to public health concerns about their carcinogenicity, the use of nitrofurans in food animals is now severely restricted in many countries, including the United States, where parenteral use was first banned in 1991 and topical use was banned in 2002. The toxicity of furazolidone in Nubian goats has been reported (Ali et al. 1984). At oral daily doses as low as 40 mg/kg for as long as ten days, goats showed signs of anorexia, weight loss, restlessness, incoordination, and hyperexcitability, with constant chewing movements, tail wagging, foot stamping, backward walking, and circling. At daily oral doses of 160 or 320 mg/kg similar signs were more severe and accompanied by frothy salivation, grunting, and bellowing and death within one week of the onset of treatment. Dinitro compounds such as dinitrophenol and dinitrocresol are used as herbicides and fungicides and are toxic to goats immediately after application to foliage, but not after the residue has dried (Guss 1977). When goats feed on sprayed foliage there may be yellow discoloration of skin and hair around the mouth and nose associated with feeding activity. Clinical signs of toxicity include fever, dyspnea, tachycardia, and convulsions. The clinical course is short and death rapidly ensues. Even with early intervention, the prognosis is guarded. No specific therapies have been reported, but use of antipyretics, anticonvulsants, and supportive care may be of some value. Pentachlorophenol is commonly used as a wood preservative for lumber. It is toxic to livestock via the mechanism of uncoupling oxidative phosphorylation. It is readily absorbed through the skin, via inhalation, or by ingestion. As a general precaution,

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pentachlorophenol-treated wood should not be used in goat buildings because of the well known wood chewing and swallowing behavior of goats. Of particular concern is freshly treated wood that has not yet dried or cured. Clinical signs of toxicity can include muscular weakness and lethargy, fever, sweating, dehydration, tachypnea, collapse, and death with rapid onset of rigor mortis. Convulsions have been reported in goats before death (Guss 1977). There is no specific treatment. Chlorpromazine and piperazine produce a fatal drug interaction when given to goats. The drug combination resulted in immediate, severe, clonic convulsions, and rapid respiratory arrest when chlorpromazine was given intravenously at a dose of 10 mg/kg after oral administration of piperazine at a dose of 220 mg/ kg (Boulos and Davis 1969).

CONGENITAL AND INHERITED DISEASES Beta Mannosidosis This heritable, lysosomal storage disease in goats is seen only in newborn kids of Nubian breeding and is characterized by intention tremors and an inability to rise. The condition is transmitted as an autosomal recessive trait. There is no treatment and carrier adults can be identified by blood test. Epidemiology The condition was first described as a neurovisceral storage disease with dysmyelinogenesis of unknown cause in newborn Anglo Nubian kids in Australia in 1973 (Hartley and Blakemore 1973). It was later characterized as beta mannosidosis in Nubian kids in Michigan in 1981 (Jones and Laine 1981). It was long thought to occur only in the goat, but is now also recognized in humans (Dorland et al. 1988) and the Salers breed of cattle (Abbitt et al. 1991). The specific molecular defect responsible for caprine beta-mannosidosis has been identified and the associated cDNA coding region has been sequenced and characterized (Leipprandt et al. 1996). It involves a single base pair deletion. Currently the caprine disease is known only in the Nubian breed or Nubian crossbreds (Shapiro et al. 1985). It has been reported in Australia, New Zealand, Fiji, Canada, and the United States. Heterozygous carriers of the trait can be identified by intermediate plasma levels of beta mannosidase. An Australian survey identified 13.7% of 988 Anglo Nubians as carriers (Sewell and Healy 1985). This suggests a significant potential economic loss for Nubian breeders. Pathogenesis The lysosomal storage diseases result from an acquired or inherited deficiency of a catabolic lyso-

somal hydrolase. In cells where the hydrolase is missing, the substrate that is ordinarily catabolized accumulates in lysosomes producing marked vacuolation and destruction of cells. In the case of beta mannosidosis, the condition is inherited as an autosomal recessive trait, transmitted with a frequency of 25% by the mating of two heterozygous parents, and the deficient hydrolase is beta mannosidase. The deficiency results in intracellular accumulation of incompletely catabolized oligosaccharides leading to marked vacuolation of cells, the characteristic histologic lesion. These substances, the disaccharide betamannosyl(1-4)-N-acetylglucosamine and the trisaccharide betamannosyl-(1-4)-N-acetylglucosaminyl-(1-4)-Nacetylglucosamine, are also excreted in the urine. While vacuolation occurs in a wide variety of cell types, lesions are most severe in the CNS and clinical manifestations of the disease in neonates are essentially neurologic. Vacuolation of neurons is accompanied by marked dysmyelinogenesis in beta mannosidosis, but the exact relationship of these two findings is unresolved. One study has reported that greater accumulation of oligosaccharide at various locations in the CNS is not directly associated with the severity of myelin deficiency at those sites (Boyer et al. 1990). Clinical Findings The clinical presentation is consistent (Kumar et al. 1986). Affected kids of either sex are born alive. They are unable to rise, and lie in lateral recumbency or drag themselves along if placed sternally. They have contracted tendons with carpal flexion, hind limb extension, and hyperextension of the pastern joints. Withdrawal reflexes are intact. There is a varying degree of facial dysmorphism including a domed skull, an elongated and narrow muzzle, small, slit-like palpebral fissures, enophthalmos, and a depressed nasal bridge. Most, if not all, affected kids are deaf, though this may be difficult to establish. Bilateral ptosis as part of Horner’s syndrome is present. Pendular nystagmus and intention tremors may be observed. The skin is thickened and the muscle mass may be decreased. Affected kids can see, smell, suckle, defecate, and urinate normally and may survive for several weeks with nursing care. Clinical Pathology and Necropsy The hemogram and serum chemistry profile are normal. Despite the facial dysmorphism and locomotor difficulties, radiographs of the skull, vertebrae, and long bones are normal. An abnormal electromyogram, with spontaneous potentials resembling positive sharp waves and fibrillation potentials, occurs in some cases.

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Techniques for measuring plasma beta mannosidase activity have been developed and can be used as an aid to distinguish normal goats from affected goats and heterozygous carriers (Healy and McCleary 1982; Cavanagh et al. 1983). Using a fluorometric technique, affected kids have markedly reduced or absent activity, with measurements below 0.2 U/l, while the activity of heterozygous carriers is always below 2.4 U/l and frequently below 1.7 U/l (Healy and McCleary 1982). Most normal, adult, noncarrier goats have activity greater than 2.1 U/l, but some may measure as low as 1.7 U/l, giving false positive results. In screening for heterozygous carriers, false positive identification rates as high as 12% can occur in goat populations when 2.1 U/l is used as the discriminate value and 2% when 1.7 U/l is used (Sewell and Healy 1985). Laboratory values for plasma beta mannosidase activity have also been reported for normal kids in the range of 66 to 222 nmol/hour/ml (Cavanagh et al. 1982). Clinically affected homozygous kids have no beta mannosidase activity in plasma and heterozygous carriers have intermediate activity. In one study, heterozygous carriers had activity measurements that averaged 47% of that of normal goats (Sewell and Healy 1985). While there is conflicting information on the effect of reproductive status and gender on beta mannosidase activity, the activity is known to decrease with increasing age up to but not after sexual maturity (Dunstan et al. 1983; Sewell and Healy 1985). Severe stresses such as transport and shearing can reduce activity into the heterozygous suspect range, so blood samples should not be taken from goats immediately after obvious stressors (Mason 1986). Affected kids also have the abnormal oligosaccharides betamannosyl-(1-4)-N-acetylglucosamine and betamannosyl-(1-4)-N-acetylglucosaminyl-(1-4)-Nacetylglucosamine present in the urine (Matsuura et al. 1983). Prenatal testing by ultrasound guided aspiration of fetal fluids has been described (Lovell et al. 1995). Abnormal accumulation of oligosaccharides was confirmed in the allantoic fluid, but not in the amniotic fluid. Diagnosis in live kids may be possible by examination of gingival biopsies for the characteristic lesions of Schwann cell vacuolation and axonal dense bodies in peripheral nerve cells (Malachowski and Jones 1983). At necropsy, muscles appear pale and small. When the contracted tendons are cut, joint motion is unimpaired. The most prominent gross lesions are in the brain. Ventricular dilation is observed in association with a marked diminution of white matter because of a paucity of myelin, especially in the cerebrum. There is also polypoid hypertrophy of the middle ear mucosa (Jones et al. 1983). Histologically, the disease is characterized by fine to coarse vacuolation of a wide variety of cell types in all

tissues. These are lysosomal storage vacuoles. Fibroblasts, macrophages, and endothelial and perithelial cells are most consistently affected in all tissues. In the CNS there is vacuolation of virtually all cell types. In addition, there is marked demyelination, especially in the brain and to a lesser extent in the spinal cord, and axonal spheroids occur throughout the white matter. Mineralization may be seen, especially in the cerebellum and globus pallidus (Lovell and Jones 1983). Ocular lesions have also been described (Render et al. 1989). Diagnosis The diagnosis is based on the characteristic presentation in newborn kids of Nubian descent, confirmation of reduced beta mannosidase activity in plasma or abnormal oligosaccharides in urine, and characteristic histology at necropsy. Differential diagnoses include hydrocephalus, congenital spinal malformations or trauma at birth, Akabane disease, border disease, and swayback. Treatment and Control There is no treatment for this condition. Control in individual herds depends on diagnosis of the condition in newborn kids and removal of the parents of affected kids from the breeding program. Goat owners purchasing Nubian goats for breeding purposes may want to screen for heterozygous carriers by assaying plasma beta mannosidase activity. More recently, a genetic test has been developed and is available through the Texas Veterinary Medical Diagnostic Laboratory. Mucopolysaccharidosis IIID Mucopolysaccharidosis IIID (MPS IIID) is an inherited lysosomal storage disease first described in human beings and later recognized in the Nubian breed of goats (Thompson et al. 1992). In human medicine the condition is also known as Sanfilippo D syndrome and Nubian goats are now used as a model for studying the human disease. MPS IIID is caused by a deficiency in N-acetylglucosamine 6-sulfatase (G6S) activity in lysosomes that results from a nonsense mutation in the 5′ region of the gene coding for expression of this enzyme. The result of this enzyme deficiency is that the catabolism of glycosaminoglycans (GAG) is disrupted so that N-acetylglucosamine 6-sulfate and heparan sulfate accumulate in the tissues and urine of affected individuals. While multiple tissues are affected, the lysosomal accumulation of these GAG in the central nervous system is mostly responsible for the clinical manifestations seen in humans and Nubian goats. The key lesions seen in the CNS of affected goats are primarily the neuronal accumulation of heparan sulfate and the excess storage

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of gangliosides in cerebral cortical and spinal cord gray matter as well as dysmyelination (Jones et al. 1998). The pattern of inheritance for MPS IIID is autosomal recessive with individuals homozygous for the defective gene expressing the disease condition. In a Michigan study of 552 Nubians using a G6S PCR-based mutation test, 25.2% of animals tested were identified as heterozygous carriers and 1.3% were homozygous for the mutation (Hoard et al. 1998). There is phenotypic variation in MPS IIID disease expression with mild and severe forms recorded in homozygous Nubian goats (Jones et al. 1998). Affected goats may be born with marked neurological deficits. One carefully studied case showed an inability to rise at birth, and a wide based stance and hyperextension of the limbs when lifted to standing. Additional signs included a fine neck tremor and horizontal nystagmus. Though the animal gradually became ambulatory, it remained ataxic and showed delayed and stunted growth. However, six other homozygous individuals in the same study showed no overt clinical signs at birth and continued normally for extended periods of time. One individual, for example, only showed signs beginning at forty-four months of age. These signs included abnormal gait, persistent head tremor, and intermittent hyperextension of the forelimbs. Another homozygous goat began showing aggressive behavior in her second year of life. The one observation common to all six mildly affected goats was growth retardation (Jones et al. 1998). Field reports suggest that mildly affected goats have decreased muscle mass and may be more prone to infection and that overt signs of disease may manifest as animals become older due to progressive accumulation of GAG in CNS and other tissues. Differential diagnosis for newborn kids should include congenital copper deficiency, congenital skeletal abnormalities such as hemivertebra, hydrocephalus, and beta mannosidosis, the other lysosomal storage disease that occurs only in Nubian goats. Akabane virus infection can also produce kids unable to rise at birth, but these kids have arthrogryposis which is not reported in MPS IIID. When progressive neurological signs appear in adult goats, scrapie must be considered as well as coenurosis where it occurs. The differential diagnosis for animals showing poor growth and decreased muscle mass should include the various nutritional, infectious, and parasitic diseases discussed in Chapter 15 relative to wasting. Testing for the presence of the G6S mutation can be performed on white blood cells harvested at the laboratory from 1 to 2 ml of blood collected in EDTA. The Texas Veterinary Medical Diagnostic Laboratory currently performs this test in the United States. The condition can be controlled through breeding based on the G6S muta-

tion status of breeding stock determined through testing. There is no treatment for the condition. Progressive Paresis of Angora Goats Ataxia, first noted at approximately four months of age, has been seen in Angora goat kids from serial litters of the same parentage in Australia. Kids had normal mental status, cranial nerve function, and reflexes, but exhibited signs of weakness including difficulty in rising, a reluctance to move, and stumbling when forced to do so. Weakness was more apparent in the hind limbs than the forelimbs. Though clinically similar to enzootic ataxia or caprine arthritis encephalitis, this condition has characteristic pathologic findings. No gross lesions were observed except muscle atrophy. Microscopic lesions were characterized by the occurrence of large cytoplasmic vacuoles in large neurons of the midbrain, brain stem, and ventral horns of the spinal cord. Chromatolysis and pyknosis were also observed. The history of reoccurrence of the condition in kids from serial litters of the same parentage suggested a hereditary basis for the condition, though the pathogenesis of the disease remains unclear (Lancaster et al. 1987). Spastic Paresis This condition is well known in cattle and is considered to be inherited in that species. Spastic paresis is characterized by intermittent unilateral or bilateral spastic contracture of the gastrocnemius muscle leading to hyperextension of one or both hind limbs. The hyperextension may be so extreme that the animal is unable to place the foot on the ground and the leg is carried straight behind. The hock is straight and the gastrocnemius muscle is palpably firm or knotted. It has been demonstrated that selective depression of gamma efferent neurons in the spinal cord by epidural administration of dilute procaine alleviates the condition, indicating that the disorder occurs from overstimulation of the myotatic (stretch) reflex (De Ley and De Moor 1980). Reports of the condition in goats are infrequent. The condition was first reported in Czechoslovakia in 1973 and involved a three-year-old male Saanen (Kral and Hlousek 1973). The goat was reluctant to stand and when forced to do so remained on its carpi with rump in the air, hind limbs overextended with the hocks straight, and the gastrocnemius tendons palpably taut. Though the diagnosis could not be confirmed, tibial neurectomy, as frequently applied in cattle, corrected the condition. More recently, the condition was reported in two familially related pygmy goats in the United States (Baker et al. 1989). In these cases, the diagnosis was supported by application of a dilute procaine epidural with subsequent alleviation of signs. Despite this evi-

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dence of spastic paresis in goats, the diagnosis must be made with caution because of the hereditary implications of the disease, which are not well defined in the caprine species. The author has observed at least two goats with classically described signs of spastic paresis that turned out to be cases of the arthritic form of CAE. The occurrence of joint pain without joint swelling is not uncommon in CAE and could lead to abnormalities of gait and posture that can mimic spastic paresis. Hydrocephalus and Hydranencephaly Hydrocephalus occurs sporadically in goats as a developmental anomaly resulting in improper drainage of the CSF. This causes increased intracerebral pressure, with thinning of the cerebral cortices, expansion of the ventricles, and possible distortion of the skull surrounding the brain. Affected kids can be delivered dead or alive. Live kids are usually dull and blind with pronounced muscular weakness; they are unable to stand unassisted or ambulate (Figure 5.7). Obvious doming of the skull is variable and does not have to be present to make a diagnosis of hydrocephalus. Hydranencephaly, which is a normotensive hydrocephalus that results from necrosis or a failure of cell growth, occurs in goats in conjunction with arthrogryposis as a result of fetal Akabane virus infection as discussed in Chapter 4. Kids with hydranencephaly have neurologic deficits similar to those seen in hydrocephalus.

NEOPLASTIC DISEASE Neoplasms of the CNS in goats are rarely found in large scale surveys of neoplastic disease of livestock. For example, there was one caprine neoplasia, a spongioma, in a report on 400 tumors of the nervous system of domestic animals (Luginbuhl 1963). However, some individual cases have been reported in the literature. In Germany, a fifteen-year-old female goat that suddenly developed a right sided heat tilt that progressed to loss of orientation and ataxia was subsequently euthanized and found to have a choroid plexus carcinoma which manifested as a well circumscribed mass in the left ventricle that compressed the cerebrum and infiltrated the left piriform lobe (Klopfleisch et al. 2006). In a report from North Carolina, glioma was diagnosed in a six-year old castrated male, mixedbreed goat that presented with a one-week history of circling, behavioral change, decreased appetite, and adipsia. A CT scan identified a large cerebral mass which was confirmed at necropsy as a glioma (Marshall et al. 1995). Lymphosarcoma (Craig et al. 1986) and malignant melanoma (Sockett et al. 1984) have also been reported involving the nervous system in goats. A malignant Schwannoma of peripheral nerve

sheaths, manifesting as 0.5 to 2 mm nodules, was recently identified in the diaphragm of a two-year-old female goat at slaughter in Spain (Ramírez et al. 2007). A goat with cerebral gliomatosis was identified in a survey of small ruminant field cases with clinical presentations of neurologic disease carried out in support of Swiss scrapie surveillance activities. The goat also had hair lice and the combination of pruritus from the lice and neurologic signs from the tumor effectively mimicked clinical scrapie (Maurer et al. 2005). Another case report of cerebral gliomatosis from Switzerland involved a three-year old Appenzell goat buck (Braun et al. 2005). The animal showed depression, generalized ataxia, hypermetria of the forelimbs, generalized hypoesthesia, bilateral mydriasis, and a decreased menace response. At necropsy, there were no gross lesions in the brain, but histologically there was extensive diffuse glial cell hyperplasia in the white matter of the cerebral hemispheres and in the brain stem.

NEUROLOGIC DISEASES OF UNKNOWN ETIOLOGY Polyradiculoneuritis Polyradiculoneuritis has been reported as a cause of progressive hind limb ataxia, hyporeflexia, and extensor rigidity in a six-week-old male kid in California (MacLachlan et al. 1982). At necropsy, there were no gross lesions but microscopically there was evidence of mononuclear inflammation and demyelination involving the meninges, nerve roots, and peripheral nerves, but not the brain or spinal cord. Similar conditions are known in man and in dogs and are hypothesized to be caused by an auto-immune reaction. Caprine Encephalomyelomalacia Caprine encephalomyelomalacia has been reported from California (Cordy et al. 1984). The condition has been described only in kids between three and a half and four months of age of dairy breeds. There is an acute onset of nervous dysfunction characterized by posterior paresis and incoordination progressing rapidly to paralysis. In some cases tetraparesis is observed. All kids were killed after a clinical course of six to ten days. There are no gross lesions at necropsy. Microscopic lesions are bilaterally symmetrical and are restricted to the gray matter of the spinal cord, particularly in the cervical and lumbosacral enlargements, and certain brain stem nuclei. Necrosis of neurons is observed.

a

b

Figure 5.7. A two-day-old kid with hydrocephalus. The kid was dull and depressed at birth and could only stand when assisted. It preferred the curled, recumbent position, as shown in Figure 5.7a. Doming of the skull was not prominent, but distension of the ventricular system was evident at time of necropsy (Figure 5.7b). (Courtesy of Dr. T.P. O’Leary.)

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256 Goat Medicine USDA: Scrapie: Nor98-like Wyoming. Quarterly Report. USDA, APHIS, VS, Centers for Epidemiology and Animal Health. United States Department of Agriculture, p.4, June 2007. USDA: United States Department of Agriculture. Scrapie Program. FY 2007 Report. USDA, APHIS, VS, National Center for Animal Health Programs, Riverdale, MD, 2007a. http://www.aphis.usda.gov/animal_health/animal_ diseases/scrapie/downloads/yearly_report.pps. USDA: United States Department of Agriculture. Voluntary Scrapie Flock Certification Program Standards. Appendix 1—Specimen Collection and Submission. USDA, APHIS, VS, National Center for Animal Health Programs, Riverdale, MD, pp.28–39, 2007b. http://www.aphis.usda.gov/ animal_health/animal_diseases/scrapie/downloads/ sfcp.pdf. USDA: United States Department of Agriculture. SOSS: Phase II: Scrapie: Ovine Slaughter Surveillance Study, 2002–2003. USDA, APHIS, VS, Riverdale, MD, 2004. http://www.aphis.usda.gov/vs/ceah/ncahs/nahms/ sheep/SOSSphase2.pdf. Uzal, F.A. and Kelly, W.R.: Effects of the intravenous administration of Clostridium perfringens type D epsilon toxin on young goats and lambs. J. Comp. Pathol., 116(1): 63–71, 1997. Uzal, F.A. and Kelly, W.R.: Experimental Clostridium perfringens type D enterotoxemia in goats. Vet. Pathol., 35(2):132– 140, 1998. Uzal, F.A., Glastonbury, J.R.W., Kelly, W.R. and Thomas, R.: Caprine enterotoxaemia associated with cerebral microangiopathy. Vet. Rec., 141(9):224–226, 1997. Vaccari, G., et al.: Identification of an allelic variant of the goat PrP gene associated with resistance to scrapie. J. Gen. Virol., 87(5):1395–1402, 2006. van der Lugt, J.J., et al.: Two outbreaks of type C and type D botulisum in sheep and goats in South Africa. J. S. Afr. Vet. Assoc., 66(2):77–82, 1995. van Tonder, E.M.: Notes on some disease problems in Angora goats in South Africa. Vet. Med. Rev., 1/2:109–138, 1975. Verster, A. and Tustin, R.C.: Treatment of cerebral coenuriosis in sheep with praziquantel. J. S. Afr. Vet. Assoc., 61(1):24– 26, 1990. Waggoner, D.J., Bartnikas, T.B. and Gitlin, J.D.: The role of copper in neurodegenerative disease. Neurobiol. Dis. 6(4):221–30, 1999. Wang, M.Z., Ye, K.X. and Hu, L.S.: Study on etiology of “lumbar paralysis” in horses, sheep, and goats. In: Proceedings, 4th Internat. Sympos. Vet. Epidemiol. Econ., Singapore, November 18–22, pp. 283–284, 1985. Weinhold, E. and Triemer, B.: Visna in the goat. Zbl. Vet. Med. B, 25:525–538, 1978. Weissmann, C. and Aguzzi, A.: Approaches to therapy of prion diseases. Annual Rev. Med., 56:321–344, 2005. Welchman, D. de B. and Bekh-Ochir, G. Spinal coenurosis causing posterior paralysis in a goat in Mongolia. Vet. Rec., 158(7):238–239, 2006. WHO: Rabies—Epidemiology. World Health Organization, Geneva. 2007. http://www.who.int/rabies/ epidemiology/en/.

WHO: Rabies-Bulletin-Europe. Rabies Information System of the WHO Collaboration Centre for Rabies Surveillance and Research. Database queries. World Health Organization, Geneva, 2007a. http://www.who-rabiesbulletin.org/ Queries/Trend.aspx. Wiedmann, M., et al.: Molecular investigation of a listeriosis outbreak in goats caused by an unusual strain of Listeria monocytogenes. J. Am. Vet. Med. Assoc., 215(3):369–371, 1999. Wilesmith, J.W., Ryan, J.B.M., Hueston, W.D. and Hoinville, L.J.: Bovine spongiform encephalopathy: epidemiological features 1985 to 1990. Vet. Rec. 130(5):90–94, 1992. Wille, H., et al.: Structural studies of the scrapie prion protein by electron crystallography. Proc. Natl. Acad. Sci. U.S.A. 99(6):3563–3568, 2002. Wilson, J., and Brewer, B.D.: Vestibular disease in a goat. Comp. Cont. Educ. Pract. Vet., 6:S179–S182, 1984. Wilson, R.D., Witzel, D.A. and Verlander, J.M.: Somatosensory-evoked response of ataxic Angora goats in suspected haloxon-delayed neurotoxicity. Am. J. Vet. Res., 43:2224– 2226, 1982. Winter, P., Hochsteiner, W. and Hogler, S.: Congenital copper deficiency in neonatal German Improved Fawn breed of goats. Tierärztliche Praxis, 30(6):378–384, 2002. Wood, J.S.: Encephalitic listeriosis in a herd of goats. Can. Vet. J., 13:80–82, 1972. Wood, J.N.L, Done, S.H., Pritchard, G.C. and Wooldridge, M.J.A.: Natural scrapie in goats: case histories and clinical signs. Vet. Rec., 131:66–68, 1992. Wouda, W., Borst, G.H.A. and Gruys, E.: Delayed swayback in goat kids, a study of 23 cases. Vet. Q. 8:45–56, 1986. Wright, H.J., Adams, D.S. and Trigo, F.J.: Meningoencephalitis after hot-iron disbudding of goat kids. Vet. Med. Small Anim. Clin., 78:599–601, 1983. Yang, W.C., Yeung, E.S. and Schmerr, M.J.: Detection of prion protein using a capillary electrophoresis-based competitive immunoassay with laser-induced fluorescence detection and cyclodextrin-aided separation. Electrophoresis. 26(9):1751–1759, 2005. Yoshikawa, T.: Atlas of the Brains of Domestic Animals. University Park, The Pennsylvania State University Press, 1968. Zamir, S.: Personal Communication. Dr. Shmuel Zamir, Chief Sheep and Goat Health Officer, Veterinary Services and Animal Health, Ministry of Agriculture and Rural Development, Government of Israel, 2007. Zanoni, R.G.: Phylogenetic analysis of small ruminant lentiviruses. J. Gen. Virol., 79:1951–1961, 1998. Zhang, L., Li, N., Fan, B., Fang, M. and Xu, W.: PRNP polymorphisms in Chinese ovine, caprine and bovine breeds. Anim. Genet., 35:457–461, 2004. Zhao, L.B., et al.: Detection of Borna disease virus P24 gene in goats in Chongqing. Vet. Sci. Chin., 36(6):460–463, 2006. Zlotnik, I.: The histopathology of the brain of goats affected with scrapie. J. Comp. Pathol., 71:440–448, 1961. Zundel, E., et al.: Virulence of Listeria monocytogenes as a biofilm: consequences for dairy farming. 10emes Rencontres autour des Recherches sur les Ruminants, Paris, France, 3–4 Decembre 2003. Institut National de la Recherche Agronomique, Paris, France, pp. 211–214, 2003.

6 Ocular System Clinical Anatomy and Examination of the Eye 257 Lids and Lashes 257 Lacrimal Glands and Ducts 258 Ocular Position 258 Conjunctiva, Sclera, and Scleral Vessels 258 Cornea 258 Iris, Pupil, and Lens 258 Retina and Ophthalmoscopic Examination 258 Cranial Nerves and Evaluation for Blindness 260 Malformations of the Globe 260 Cyclopia 260 Microphthalmia 260 Lid Abnormalities 260 Entropion 260 Tumors 261 Conjunctivitis and Keratoconjunctivitis 261 Infectious Keratoconjunctivitis 262 Noninfectious Keratitis 265 Anterior Uveitis, Cataracts, and Glaucoma 266 Causes of Anterior Uveitis 266 Treatment of Anterior Uveitis 267

Although ophthalmologists have in general paid little attention to the goat in their writings, several published reviews are oriented toward caprine ophthalmology (Wyman 1983; Baxendell 1984; Moore and Whitley 1984; Whittaker et al. 1999). Most aspects of anatomy and therapy apply across species lines. Any good ophthalmology text, then, should be useful for the practitioner needing more information than this chapter supplies.

CLINICAL ANATOMY AND EXAMINATION OF THE EYE The history elicited from the owner may suggest a problem with ocular structures or vision. The goat may have a hesitant gait or refuse to move or pass through a gate. The animal may carry its head abnormally elevated or near the ground. A report of normal vision should be verified by the examiner; visual loss may not be apparent until the goat is placed in unfamiliar surroundings. The eyes should also be examined relative to systemic conditions (i.e., dehydration, anemia, icterus, septicemia, hemorrhagic diseases) and during prepurchase or breeding soundness examinations. Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Cataracts 267 Glaucoma 267 Retinal Changes 268 Papilledema 268 Chorioretinitis 268 Chorioretinopathy 268 Retinal Detachment 269 Amaurosis 269 Blindness versus Failure to Blink 269 Blindness versus Severe Depression or Toxemia 269 Polioencephalomalacia 269 Enterotoxemia 269 Lead Poisoning 270 Hydrocephalus 270 Vitamin A Deficiency 270 Coenurosis 270 Miscellaneous Causes of Central Blindness 270 Residual Blindness 270 Enucleation 270 References 271

Lids and Lashes The upper and lower eyelids normally are tightly apposed to the globe. They should neither roll inward (entropion) nor gape outward (ectropion). Lashes should not be in contact with the cornea. The examiner should note the location of any long, tactile hairs before evaluating vision by the menace response. Touching the lids near the medial canthus should evoke the palpebral reflex (blinking and retraction of the globe). This reflex requires function of cranial nerves V (sensory branches of trigeminal nerve) and VII. The third eyelid (nictitating membrane) is normally unobtrusive. It can be seen better if the globe is retropulsed, using digital pressure through the eyelids. Topical anesthesia permits grasping of the third eyelid with smooth forceps so that its posterior surface can be inspected for lesions or foreign bodies. Prolapse of the third eyelid occurs in some cases of tetanus. Passive prolapse of the nictitans occurs in conditions causing enophthalmos, including dehydration or emaciation, as well as in neurologic diseases accompanied by Horner’s syndrome (see Chapter 5). 257

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Lacrimal Glands and Ducts The lacrimal apparatus of the goat has been reviewed by Sinha and Calhoun (1966). Lysozyme has been identified in goat tear samples (Brightman et al. 1991). Plasma cells in the nictitating gland secrete IgA into the tear film (Schlegel et al. 2003). Normally no staining or wetness occurs beneath the goat’s eye, neither is there a deep recess filled with exudate near the medial canthus analogous to the infraorbital gland of sheep. The nasolacrimal duct can be catheterized from the ocular puncta (Moore and Whitley 1984). Ocular Position The ruminant eye normally maintains a constant position relative to the ground rather than remaining centered between the lids. This can make ocular examination frustrating if the goat’s head cannot be restrained in the position required to expose the structures of interest. Abnormal function of the nerves supplying the extraocular muscles (cranial nerves III, IV, VI) affects ocular position. Dorsomedial strabismus, for instance, sometimes occurs in polioencephalomalacia. Mydriasis and strabismus may occur with botulism as a result of paralysis of intrinsic and extrinsic ocular muscles (Wyman 1983). Normal nystagmus (vestibular nystagmus) occurs when the head is slowly turned to one side and has its quick phase in the same direction as the head movement. Normal postrotatory nystagmus (direction opposite the direction of rotation) lasts for less than ten seconds. Exophthalmos (protrusion of the globe) may be due to a retrobulbar abscess or tumor. Ideally, examination of the orbit by ultrasound or computed tomography, followed by guided aspiration of cells or fluid from the lesion, allows a diagnosis to be made. Enucleation may be required to resolve a retrobulbar abscess. It is unlikely to cure the tumors most likely in this location (lymphosarcoma, enzootic nasal tumor). See Chapter 9 for further discussion of enzootic nasal tumor. Conjunctiva, Sclera, and Scleral Vessels Everting the eyelids permits inspection of the conjunctiva (Figure 6.1). Rotating the head upward and to one side exposes bulbar conjunctiva and the deeper sclera and its vessels. A pale white color with almost invisible blood vessels occurs with severe anemia, and yellow sclera is indicative of icterus. A brownish discoloration of this and other mucous membranes occurs with nitrate poisoning, a purplish color with cyanotic conditions, and bright red coloration with cyanide poisoning. Vessels may appear congested with ocular, regional, or systemic inflammatory or toxic diseases. Cornea The cornea is normally clear and moist. Oblique lighting and observing the clarity with which the iris

Figure 6.1. The lower lid has been everted to expose the conjunctiva. This goat had a packed cell volume of 21%. (Courtesy Dr. M.C. Smith.)

can be visualized aid in differentiating cloudiness of the cornea from lens opacity. If the cornea is lightly touched with a finger or a wisp of cotton, the corneal reflex results in the same blinking and globe retraction, via the same pathway, as the palpebral reflex. Iris, Pupil, and Lens A strong and well-focused light source should be used to evaluate direct and consensual pupillary response (optic nerve and parasympathetic fibers traveling with the oculomotor nerve, midbrain). Pupillary responses may be intact in a blind animal, and they may be almost impossible to elicit in an apprehensive goat. The pupil is oval, becoming more rectangular in bright light, and has granula iridica (corpora nigra) attached to both its dorsal and its ventral rim. Various toxicities may affect the pupil (e.g., mydriasis with chlorinated hydrocarbons [Choudhury and Robinson 1950] or miosis with organophosphates). The anterior chamber, between cornea and iris, should be examined for hyphema, hypopyon, and aqueous flare (cells and protein, often indicative of anterior uveitis). If a cataract (opacity of the lens or its capsule) is detected, the density of the cataract should be evaluated. If a portion of the retina is clearly visible in a blind animal, any cataract that may be present is not the cause of blindness. Retina and Ophthalmoscopic Examination The goat’s fundus can usually be examined without resorting to mydriatics. If a detailed examination is desired, and if the examiner is willing to wait fifteen to thirty minutes for its effect, 1% tropicamide may be used to dilate the pupil (Figure 6.2). This should not be done until after pupillary response has been evaluated and diagnostic cultures or scrapings have been performed.

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Figure 6.2. The normally rectangular pupil has been dilated with tropicamide to permit a thorough fundus examination. (Courtesy Dr. M.C. Smith) Figure 6.4. The fundus of a normal Boer goat. (Courtesy Dr. M.C. Smith.)

Figure 6.3. The fundus of a Saanen goat. o.d. = optic disc, a = arteriole, t.n. = tapetum nigrum, o.c. = optic cup, v = venule.

Hyaloid remnants on the optic nerve head and continuing into the vitreous body are commonly found in adult ruminants, including four of ten goats in one study (Schebitz and Reiche 1953). Presence of blood within the hyaloid vessel is also considered normal until eight weeks of age in lambs, although this has not been investigated in kids. Photographs of the fundus of goats have been published (Rubin 1974; Whittaker et al. 1999; Galan et al. 2006b). A diagram of a goat fundus is provided in Figure 6.3 and a normal Boer goat fundus is illustrated in Figure 6.4. The fundus is usually in focus with a direct ophthalmoscopic setting of –1D to –5D. The

optic disc is rather round or oval, whereas in the sheep it is often more kidney-shaped. The optic disc in goats is frequently located totally within the tapetal fundus (tapetum lucidum, yellow to bluish green). In cattle and sheep it is usually situated in the nontapetal fundus (tapetum nigrum, brownish) just beneath the horizontal junctional area of tapetal and nontapetal fundus. The optic disc is grayish pink and sharply demarcated, and has a small funnel-shaped physiologic cup. The broader veins enter the middle of the disc while the thinner, redder arteries originate like rays from a pericentral location (Schmidt 1973). There are more blood vessels than in sheep or cattle. Galan et al. (2006b) report three to six retinal arteries in the goat, often branching from a common artery that emerges from the dorsotemporal portion of the disc. There are many stars of Winslow which are black dots in the tapetum lucidum where choriocapillaris vessels penetrate the tapetum. Fluorescein angiography of the normal goat fundus has been described (Galan et al. 2006a). Ultrasonography can be used to evaluate the contents of the globe and the retrobulbar area, as is done routinely in companion animal medicine. Ideally, both a 7.5-MHz probe and an offset pad are used. The globe can be imaged through the upper eyelid or directly through the cornea. Tranquilization is followed by application of a local anesthetic to the cornea, and the probe is placed on lubricating jelly on the lid or on a mound of sterile ocular lubricating gel on the cornea. Normal chamber fluid is hypoechoic, while the posterior lens capsule and retina are hyperechoic. Conditions that might be demonstrated by ultrasound include luxated lens, retinal detachment, or a retrobulbar abscess or tumor (Toal 1996).

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Cranial Nerves and Evaluation for Blindness The optic disc is the optic nerve head. It may be swollen with papilledema or with optic neuritis. Unilateral blindness may be detected by covering one eye and observing the goat’s behavior in a strange environment. Young kids often visually follow a bottle of milk when other items fail to attract their interest. The complete visual pathway, including optic nerve and cerebral cortex, is also evaluated by the menace response. Fingers are moved vertically or quickly spread apart (to decrease air currents) in front of each eye in turn. Lashes and tactile hairs must not be touched. The palpebral reflex (cranial nerves V and VII) should be checked if the goat does not blink in response to the menacing gesture.

MALFORMATIONS OF THE GLOBE Various chemical or viral teratogens may interfere with embryologic development of the eyeball. Cyclopia Veratrum californicum, if consumed on approximately day four of pregnancy, can cause cyclopia in kids and lambs (Binns et al. 1972). Deformation of the skull (“monkey face”), absence of the pituitary, and other brain malformations may also occur. This problem can be prevented by not allowing the buck access to the females when grazing on the plant might occur. The author has seen cyclopic kids in New York, where Veratrum californicum does not grow, and several case reports from India also did not identify a cause of the malformation (Raju and Rao 2001). It is logical that other toxins or tissue insults occurring at the critical stage of embryologic development, when a single optic field is dividing in two, could also result in cyclopia. Microphthalmia Microphthalmia and other congenital deformities including lens luxation or aphakia have been reported in lambs when pregnant ewes have grazed on seleniferous pastures. Anophthalmia has been caused by exposure of a pregnant ewe to apholate, an insect chemosterilant (Younger 1965). The effects on caprine ocular structures of these compounds or of in utero viral infections have not been reported.

LID ABNORMALITIES Lacerations of the eyelids should be repaired using standard techniques. Skin diseases involving the lids (e.g., contagious ecthyma, mange, staphylococcal dermatitis, zinc deficiency) are described in Chapter 2. When skin lesions are restricted to the eyelids, the possibility that they are caused by ocular discharge or rubbing in response to ocular discomfort should be investigated. Injuries to the face may occur because of

blindness. Small palpebral fissures, thickened nonpliable lids, and partial prolapse of the nictitating membrane occur in Nubian kids with inherited beta mannosidosis (Render et al. 1989), which is discussed in Chapter 5. Entropion Entropion is the turning inward of the lower lid or both eyelids so that the eyelashes rub on the cornea. The condition is painful and results in tearing and retraction of the eyeball. The lids are partially closed; the lashes may be stuck together with exudate. Congenital or Primary Entropion When a kid’s eyelids are malformed from birth, the condition is usually recognized within the first few days of life. The longer the entropion remains uncorrected, the more likely that a serious infection or corneal ulceration will result. It is probable, though unproven, that this condition has a hereditary component. Thus, if surgical treatment is required on humane grounds, the identity of the goat should be recorded so that it can be slaughtered for meat or sterilized rather than being permitted to reproduce. Spastic Entropion Older animals may develop entropion as the result of prolonged squinting when another painful eye condition is present (Figure 6.5). Typical examples are severe keratoconjunctivitis or the presence of a foreign body in the eye. If one goat continues to suffer from “pinkeye” after the rest of the herd has recovered, a point should be made of examining its eyelids. When the entropion is of spastic origin, surgically altering the eyelids is not always necessary. Instead, the lid position can be corrected by sutures or wound clips long enough for the initial and secondary problems and pain to be resolved. Other Causes of Secondary Entropion It is possible for entropion to follow a previous injury to and deformation of the eyelid. A small or collapsed globe also permits the lids to roll inward, as does retraction of a painful eyeball deeper into the orbit. Severe dehydration and emaciation (as from starvation or parasitism) are perhaps the most common causes of secondary entropion. Corrective Measures The literature is replete with techniques for correction of entropion in goats and in other species (Rook and Cortese 1981; Wyman 1983; Baxendell 1984; Moore and Whitley 1984; Whittaker et al. 1999). In general, the veterinarian should not rush into a complicated and therefore expensive technique without giving con-

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a

Figure 6.5a. Chronic spastic entropion with severe keratitis and hair loss.

b

Figure 6.5b. Same goat, twelve days after surgical correction of the entropion by removal of an ellipse of skin below the eye. (Courtesy Dr. M.C. Smith.)

sideration to one of the more temporary but often effective methods developed by ingenious shepherds and private practitioners. One such simple but versatile technique is the use of Michel wound clips (Eales et al. 1984) (Miltex Instrument Co., New York, NY) or metal surgical staples, three or four per affected lid, to pinch up a fold of skin adjacent and parallel to the lid margin. No anesthesia is required; it is simple to remove and replace a clip if the effect of its placement is not immediately satisfying, and the clips fall out on their own over time. The owner of a newborn kid may be able to achieve correction simply by drying the area and manually rolling the lid margin outward as often as possible over the course of one or two days. Another version of this approach is to roll superglue onto the skin below the eyelid with a toothpick (which only serves as the applicator), causing the skin to evert and adhere to itself

(Mongini 2007). Tensing of the lid by injection of penicillin in the same site where clips would be placed is also effective. A slightly more traumatic approach is to crush a fold of skin with hemostats; the ensuing swelling everts the lid. Naturally, any additional causes of ocular pain should be identified and treated. An antibiotic ointment is administered for several days, until the eye appears to be comfortable. Surgical techniques, mostly adapted from canine ophthalmology, include removing an ellipse of skin alone or skin plus orbicularis muscle. Although initially effective, these methods carry the danger of creating an ectropion when the scar contracts. Thus, they should not be used for the treatment of very young kids or of goats with a simple, spastic entropion. Tumors A hemangioma of the third eyelid has been reported in a goat in England (Matthews 1992). Tumors of the third eyelid (type not specified) have been observed in Saanen goats in Australia (Baxendell 1984) and other regions where animals are exposed to high intensity sunlight. Conjunctivitis, lacrimation, and even a purulent secretion may result. The tumor is surgically removed with the aid of tranquilization, local anesthesia, and (if available) electrocautery. Eye ointments are used postoperatively. The Angora goat (because of lack of protective pigmentation) is also considered to be predisposed to ocular squamous cell carcinoma. Warts may involve the eyelids. They are discussed in detail in Chapter 2. Most warts on the face regress spontaneously, but excision may be desirable in select cases. They need to be distinguished from contagious ecthyma lesions, which are also proliferative and selflimiting but have an important zoonotic potential. Almost any lesion on the eyelid, including warts and other tumors, can become secondarily infected with staphylococci.

CONJUNCTIVITIS AND KERATOCONJUNCTIVITIS Infectious keratoconjunctivitis is known to the layperson as “pinkeye.” A number of etiologic agents have been incriminated. When only one or two animals are affected, it becomes more difficult to distinguish between an infectious and an irritant cause. In fact, many sources of irritation, such as bright sunlight, dusty hay, and dust blown into the eyes by wind or transport in an open vehicle, can predispose the goat to development of an infection. Flies and hay or grass contaminated by ocular secretions can spread the agents to other goats. A herd outbreak may follow introduction of a carrier animal or attendance at a show. Another common source of irritation to conjunctiva and cornea is entropion. Entropion should be suspected in young kids with tearing; its management is

262 Goat Medicine

discussed above. In an older animal with sudden occurrence of entropion, the possibility that a foreign body remains in the conjunctival sac or beneath the third eyelid must be considered and investigated by thorough examination. Infectious Keratoconjunctivitis Etiology Mycoplasma and Chlamydophila are currently believed to be the most common causes of keratoconjunctivitis in goats in the United States. Numerous other agents are rarely involved or are exotic to North America. Mycoplasma Mycoplasma conjunctivae has been isolated from naturally occurring cases of pinkeye in goats and in sheep and has induced the disease in experimental studies (Barile et al. 1972; Baas et al. 1977; Trotter et al. 1977). It also can exist in a carrier state in the conjunctival sac of clinically healthy eyes. Mild forms of the disease are self-limiting and last approximately ten days, although clinical signs have been reported as persisting as long as twelve weeks. Other mycoplasma species isolated from goats with keratoconjunctivitis include Mycoplasma agalactia, M. mycoides subsp. mycoides, large colony type (McCauley et al. 1971; Bar-Moshe and Rapapport 1981), M. capricolum (Taoudi et al. 1988), and Acholeplasma oculi (Al-Aubaidi et al. 1973). Because these agents can be associated with mastitis, pleuropneumonia, or arthritis, it may be easier to demonstrate the organism in other disease processes in the same goat. A report of M. mycoides var. capri from the United States (Jones and Barber 1969) probably represents a misidentification of M. mycoides subsp. mycoides (DaMassa et al. 1984). Chlamydophila remains an important differential, especially if arthritis or pneumonia is concurrent. Chlamydophila Chlamydial conjunctivitis has been recorded as a contagious disease of young goats and adults (Baas 1976; Eugster et al. 1977). In sheep, recurrence of chlamydial keratoconjunctivitis within a few weeks after clinical remission and an outbreak duration of several months have been recorded (Andrews et al. 1987). Lymphoid follicles are reported to develop in the conjunctiva early in the course of the disease. The current name applied to the chlamydial species causing conjunctivitis in small ruminants is Chlamydophila pecorum (Nietfeld 2001). Rickettsia Colesiota (Rickettsia) conjunctivae has been proposed as an etiologic agent for pinkeye in goats and sheep (Rizvi 1950). Most reports were based on cytology and

predated the knowledge that chlamydia and mycoplasma are commonly involved, and thus rickettsia have fallen out of favor as being involved in the syndrome (Jones et al. 1976). The reported clinical signs, including occasional prolonged outbreaks, are indistinguishable from the disease produced by the other agents. However, experimental subconjunctival injection of the Q fever agent (Coxiella burnetii) has produced severe keratoconjunctivitis in goats, with rickettsia demonstrable in scrapings (Caminopetros 1948). Other Possible Agents The isolation of a bacterium from the conjunctival sac of a goat with keratoconjunctivitis is not adequate proof of causality. It is possible that Moraxella (Branhamella) (Neisseria) ovis is sometimes involved in the pathogenesis (Bulgin and Dubose 1982). Conjunctivitis but not severe keratitis has been reproduced experimentally in goats using a strain of Moraxella (Branhamella) ovis isolated from an outbreak of keratoconjunctivitis (Bankemper et al. 1990), but this same organism appears to be common in normal eyes of goats, at least in some herds (Pitman and Reuter 1988). Staphylococcus aureus has also been isolated from ocular swabs of healthy goats (Adegoke and Ojo 1982). In cattle and sheep, Listeria monocytogenes has been associated with a keratitis resulting from direct inoculation of contaminated silage into the eye (Evans et al. 2004). Moraxella bovis, an important cause of pinkeye in cattle, is rarely involved in caprine keratoconjunctivitis. The organism is rod-shaped, whereas Moraxella (Branhamella) ovis is a coccus. Commercial Moraxella vaccines have no place in caprine medicine. A very closely related species, Moraxella caprae, is also a rod and has been isolated from normal goats (Kodjo et al. 1995). The significance of this organism as a potential cause of keratoconjunctivitis is unknown. Infectious bovine rhinotracheitis (IBR) virus has been isolated from a goat that developed severe keratoconjunctivitis after five days of treatment with an antibiotic preparation containing corticosteroid for respiratory disease (Mohanty et al. 1972). Most experimental inoculations of goats with the IBR virus have produced seroconversion but only mild clinical signs in addition to fever. Borna disease is an infectious meningoencephalomyelitis of viral origin that affects horses and sheep in middle and eastern Europe and may be transmitted by ticks. Conjunctivitis and epiphora have been reported as ocular signs. Central nervous system involvement can lead to blindness as well as other neurologic signs. Antibodies have been found in goats, but spontaneous cases of the disease have rarely been reported in this species (see Chapter 5).

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The rinderpest and peste des petits ruminants paramyxoviruses cause high fever and erosive lesions in the alimentary tract of ruminants. Ocular signs may include increased lacrimation and a serous conjunctivitis that turns mucopurulent. Gray, elevated fibrinonecrotic lesions in the conjunctiva may eventually slough, leaving an ulcer (Williams and Gelatt 1981). Goats with capripox infections sometimes develop oculonasal discharge, conjunctivitis, and keratitis, in addition to fever and anorexia (Patnaik 1986). The typical skin lesions caused by the virus are discussed in Chapter 2. Thelazia spp., the eyeworms, can cause conjunctivitis or keratitis in sheep, and probably in goats. Thelazia rhodesii occurs in goats as well as cattle, sheep, and other species, and is cosmopolitan in Europe, Asia, and Africa. Thelazia californiensis is widely distributed in the United States, but goats are not mentioned as harboring the parasite (Soulsby 1982). The nematodes are small (7 to 18 mm) and slender. They may be found in the conjunctival cul-de-sacs, behind the third eyelid, or swimming across the surface of the cornea. Sometimes they invade the nasolacrimal duct. A topical anesthetic is applied and the eye is irrigated with sterile saline to remove the worms (Wyman 1983). Alternatively, topical application of an avermectin, such as a drop or two of 1% moxidectin for injection, kills the parasite (Lia et al. 2004). Systemic levamisole or avermectins should also kill the worms (Whittaker et al. 1999). Control of nonbiting flies, which serve as vectors (Otranto and Traversa 2005), is desirable. A single Setaria cervi worm longer than 1 inch was found in the aqueous humor of a goat in India. The goat exhibited continuous unilateral lacrimation. The worm was successfully removed under local anesthesia (Emaduddin 1954). Migrating larvae of Gedoelstia hassleri (nasal botfly) cause keratoconjunctivitis and panophthalmitis in goats and other species in endemic areas of South Africa (Basson 1962). Trypanosoma brucei and T. rhodesiense cause blepharoconjunctivitis and keratitis in goats (Losos and Ikede 1972). In many tropical and subtropical countries, screwworm larvae may invade fresh wounds on the head or ocular tissues infected with keratoconjunctivitis. A foul odor and brownish exudate are produced. Other opportunistic fly larvae may then infest the lesions. Besnoitiosis is a parasitic disease of goats as well as cattle and horses in southeastern Europe, Africa, and New Zealand. The causative agent in goats is a Besnoitia species, possibly different from B. besnoiti of cattle (Njenga et al.1993). Cats that eat cysts in infected tissues develop an intestinal infection and excrete infective forms in their feces. Clinical signs in goats include dermatitis, alopecia, and infertility. Ocular cysts (white, elevated, sand-like foci) on the scleral

conjunctiva are useful for field diagnosis of the infection (Bwangamoi et al. 1989). Mycotic keratitis, although relatively common in horses, seems to be rare in ruminants (Wyman 1983) and specific reports in goats are lacking. Isolation and identification of the fungus are required before the diagnosis can be made. A chronic keratitis, plaque-like growths on the cornea, or severe keratomalacia might prompt attempts to culture a fungus, especially if there is a history of treatment with antibiotics and corticosteroids together. Therapy is difficult and expensive. The practitioner should consult with an ophthalmologist. Clinical Signs Early or mild keratoconjunctivitis results in lacrimation; the side of the face is wet below the eye. The conjunctiva is also red and swollen (chemosis) (Figure 6.6). Over several days, hyperemia of the conjunctiva increases, follicle formation occurs, and neovascularization of the cornea may develop. The cornea may be slightly hazy at the limbus or entirely opaque (Baxendell 1984). A few animals develop a corneal ulcer that can be demonstrated with fluorescein stain (Figure 6.7), and that ulcer may perforate. The eye is painful and held partially closed; blinking is frequent. If both eyes are opaque or ulceration occurs, the goat will lose body condition because it does not forage well. Totally blind animals on range may die (Eugster et al. 1977). Diagnostic Techniques The various etiologic diagnoses for infectious keratoconjunctivitis cannot be distinguished on the basis of clinical signs; laboratory assistance is required. Mydriatics, topical anesthetics, or vital stains should not be used until after diagnostic samples have been taken.

Figure 6.6. Early keratoconjunctivitis with chemosis and slight ocular discharge. (Courtesy Dr. M.C. Smith.)

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cillary (McCauley et al. 1971) and signet-shaped bodies are found attached to or within epithelial cells in mycoplasmal infections. Moraxella (Branhamella) ovis organisms are larger than mycoplasma and more uniform in shape, and stain more intensely (Dagnall 1994). Rickettsia are described as small, Gram-negative, highly pleomorphic bodies that may be both intracytoplasmic and free (Beveridge 1942; Rizvi 1950). Pigment granules or stain precipitates can be confusing, and visible evidence of an etiologic agent may be lacking, even when cultures are positive. Treatment Figure 6.7. A corneal ulcer is green from uptake of fluorescein stain. Marked neovascularization of the cornea indicates chronicity. (Courtesy Dr. M.C. Smith.)

CULTURES. A premoistened sterile polyester or calcium alginate swab is rubbed briskly across the conjunctiva and placed in transport media (such as Amies). If possible, personnel at the diagnostic laboratory should be consulted regarding media, because chlamydia and mycoplasma can be difficult to isolate. If the laboratory does a polymerase chain reaction test for chlamydia, use of transport media may dilute the sample too much for good results. Dry cotton swabs are less desirable for fastidious organisms. It is also important to take samples from early lesions; secondary bacteria, leukocytes, and various products of immune mechanisms interfere with isolation efforts. SCRAPINGS FOR IMMUNOFLUORESCENCE TESTING. Scrapings from the palpebral conjunctiva (especially lymphoid follicles) can be made with a wooden spatula designed for obtaining Pap smears, the butt end of a disposable scalpel blade, or with the bevel of a sterile, disposable 20-gauge needle. The tissue thus obtained is spread on several microscope slides. Many laboratories consider fluorescent antibody testing for chlamydia to be easier than culturing this agent in embryonated eggs or tissue culture cells. EXFOLIATIVE CYTOLOGY. Interpretation of cytological preparations from conjunctival scrapings can be very difficult, even for trained people. Practitioners should consider preparing duplicate slides to simplify later consultation with an ophthalmologist or diagnostic laboratory. Superficial cells can be harvested with minimal distortion by rolling a dry swab across the conjunctiva and then across the slide, as is done for canine vaginal smears. Deeper scrapings are obtained with a blade or small spatula. New methylene blue, Wright, Giemsa, Dif-Quik, or Gram stain is typically used. Large basophilic, Gram-negative cytoplasmic inclusion bodies in epithelial cells occur with chlamydial conjunctivitis but are difficult to find after the first week (Wyman 1983). Smaller basophilic coccoba-

The intensity of treatment varies according to the number of infected goats and the concern of the owner. What follows is most appropriate for single pets or valuable animals. The eye should be irrigated with physiologic saline, sterile saline for contact lens wearers, or clean (preferably previously boiled) water to remove exudates and dust or other foreign matter. Although antibiotic drops are theoretically better than ointments, it is inconvenient for the owner to apply drops every two hours. Ointments are generally effective if given at least twice (or better, three to four times) a day. Several antibiotics have been clinically effective, but it must be remembered that many animals heal uneventfully without treatment. Given the spectrum of agents associated with keratoconjunctivitis, a tetracycline eye ointment is a reasonable choice. In countries where its use is permitted, chloramphenicol ointment might be effective, although systemic chloramphenicol was not effective in treating sheep with keratoconjunctivitis (König 1983). It is illegal to administer chloramphenicol to goats in the United States, because all goats are assumed to be food-producing animals despite the owner’s plans for the individual. Powders and aerosols are irritating to the eyes and ideally should not be used, but they have been reported to give good results. When economics become an important consideration, as when many goats are affected or the whole herd is being treated simultaneously to try to end a prolonged epizootic, it may not be possible to use ophthalmic ointments. Experimentation may identify a nonirritant mastitis ointment containing a suitable antibiotic that is better than no treatment at all. Under similar circumstances, intramuscular injections of long-lasting tetracycline have prevented relapses in sheep affected with Mycoplasma conjunctivae and other agents (König 1983; Hosie 1988). Intramuscular tylosin (200 mg/goat/day) has afforded good results in goats treated early in the course of chlamydial keratoconjunctivitis (Eugster et al. 1977). Subcutaneous administration of these antibiotics would also be effective and less painful. A newer macrolide antibiotic, tulathromycin, has not yet been evaluated in small ruminants but is effective in treating

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keratoconjunctivitis in beef cattle (Lane et al. 2006). Milk contamination makes systemic antibiotic treatment unjustifiable in most dairy herds. In fact, the possibility of milk contamination from eye ointments has apparently not been investigated. Corticosteroids are available in many different topical and injectable preparations of varying antiinflammatory effect and penetrating ability (Bistner 1986). Corticosteroids are not necessary and are contraindicated if an ulcer is present. A subconjunctival injection of a depot form of corticosteroid may be helpful to control neovascularization after extensive keratitis. The eye must be “quiet” and the cornea free of ulcers, as demonstrated by fluorescein staining, before such a treatment is performed. In general, it is best to dispense an ointment without steroids because the owner is likely to use whatever product is on hand to treat undiagnosed eye problems of goats or other animals at a later date. Ulcerated eyes should be observed several times a day for descemetocele formation. If perforation of the cornea appears imminent, a conjunctival flap, third eyelid flap, or tarsorrhaphy is indicated to protect and support the cornea. The third eyelid flap is probably easiest. Local anesthesia with an ophthalmic anesthetic, paralysis of the eyelids with 1 or 2 ml of injectable anesthetic (diluted if the goat is small) over the auriculopalpebral nerve (on the lateral surface of the zygomatic arch), and light tranquilization with xylazine are employed. Mattress sutures of 00 chromic gut that pass through the full thickness of the upper lid but do not penetrate the bulbar aspect of the third eyelid pull the cartilaginous portion up to the upper lid (Moore and Whitley 1984); small buttons or pieces of tubing on the outside of the lid prevent pressure necrosis of the skin. Follow-up care includes continued therapy with antibiotic ointment and close observation for loosening of the sutures. Misplaced sutures abrade the cornea. Absorbable sutures dissolve in two to three weeks, and nonabsorbable sutures should be removed at this time. As a simpler alternative to surgery for severe corneal ulcers, the author has seen excellent response to topical 5% silver nitrate, a few drops applied once a day for five days in conjunction with systemic oxytetracycline. This solution is not available commercially but can be approximated by dissolving the material coated onto one Grafco® silver nitrate applicator stick (Atlanta, GA) in 1 ml of sterile water. The totally opaque soft cornea is firm and shiny again in a few days, although total clearing of the cornea can be expected to require more than a week (Figure 6.8). Because the silver nitrate appears to sting, pretreatment with a topical anesthetic is advised. In human medicine, both 1% silver nitrate solution and 2.5% povidone iodine solution have been effective in killing microorganisms in

a

Figure 6.8a. A totally opaque and softened cornea from severe bilateral keratoconjunctivitis.

b

Figure 6.8b. The same cornea, five days after initiation of treatment with systemic oxytetracycline and topical 5% silver nitrate. The cornea is firm, shiny, and clearing. (Courtesy Dr. M.C. Smith.)

the eye for prophylaxis of ophthalmia neonatorum (Isenberg et al. 1994). Noninfectious Keratitis Not all cases of keratitis begin as infectious conjunctivitis. Abrasions Foreign bodies (in addition to eyelashes) may abrade or penetrate the cornea. The eye is painful, and fluorescein staining reveals a defect in the corneal epithelium. Treatment for shallow abrasions is with an antibiotic ointment after careful search for a foreign body in the fornix or behind the third eyelid. If the injury has reached the level of Descemet’s membrane, and the inner layer of the cornea bulges outward, a conjunctival or third eyelid flap is indicated. A corneal stromal ulcer with lysis (melting) as a result of collagenase production may appear soft and

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gelatinous or may resemble a deep abrasion. When any doubt exists as to the origin of the lesion, anticollagenase drugs (Mucomyst® [Bristol-Myers Squibb, Princeton, NJ] topically) and aspirin (100 mg/kg twice daily orally) should accompany placement of a conjunctival flap. If the full thickness of the cornea has been perforated but iris has plugged the hole, consultation with or referral to an ophthalmologist is desirable. A collapsed eyeball is generally best enucleated. Exposure Secondary to Facial Nerve Deficit Listeria organisms often enter the brain stem along a cranial nerve. If the facial nerve is thus involved, unilateral paresis or paralysis of the eyelids may occur before any signs of central nervous system disturbance are recognized. The goat that can no longer blink may incur a shallow abrasion to the cornea, which the owner recognizes because of lacrimation, conjunctival injection, corneal clouding, and photophobia. It is very important for the veterinarian to evaluate ipsilateral tonus of lids, ear, and lip. Although it may be impossible to distinguish a facial nerve paralysis of traumatic origin or secondary to otitis media from early listeriosis, treatment with penicillin or tetracycline for one week is justified because the prognosis for an animal with listeriosis is so much worse when the signs are unequivocal. The cornea dries out and becomes opaque in more advanced listeriosis or other long-standing facial nerve paralysis. A lid-splitting suture pattern to hold the lids in apposition over the cornea prevents additional damage and decreases the frequency with which application of ointments is required during the prolonged recovery period, until nerve function returns. In general, local therapy for exposure keratitis should include antibiotics to prevent secondary infection and atropine for cycloplegia (Rebhun and deLahunta 1982). Uveitis and even hypopyon can be expected in severely affected goats. Vitamin A Deficiency Bilateral corneal opacity, lacrimation, and diarrhea were observed in kids born in a goat herd experiencing severe vitamin A deficiency due to six months on dry pasture. All signs disappeared after improvement of the diet (Caldas 1961). Night blindness, lacrimation, and corneal ulceration were reported in adult goats kept on an experimental vitamin A deficient diet for periods as long as two years (Schmidt 1941; Majumdar and Gupta 1960; Dutt and Majumdar 1969). Toxins Phenothiazine was once commonly used as an anthelmintic. If metabolism is not complete, phenothiazine sulfoxide reaches the aqueous humor and is a

primary photosensitizing agent; it induces uveitis, corneal endothelial damage with subsequent edema, and keratitis (Enzie and Whitmore 1953). Young goats should be kept out of direct sunshine for three days after receiving this drug. Keratoconjunctivitis sicca, or dry eye, is one of the signs associated with locoweed poisoning (Astragalus spp). Drying out of the eyes may be caused by inadequate blinking and failure of neurologic stimulation to the lacrimal glands or by reduced tear production capabilities of the glands. The imported fire ant (Solenopsis invicta) is present in the south central United States. Ants occasionally attack weak or debilitated animals, injecting a necrotoxic venom into the victim. Necrotic ulceration of conjunctiva and cornea has been observed in a goat stung by these ants (Joyce 1983). Caprine Mucopolysaccharidosis-IIID A recessive genetic defect (G6S) of Nubian goats which causes a deficiency of N-acetylglucosamine-6sulfatase results in the accumulation of glycosaminoglycans in lysosomes. Growth retardation has been reported clinically. One severely affected kid was ataxic and developed mild, nonprogressive corneal clouding; histologically there was vacuolation of cells in the cornea as well as in the brain (Jones et al. 1998). A survey of 552 purebred Nubian goats in Michigan revealed that 25% of the animals were heterozygous for the mutation and 1.3% were homozygous (Hoard et al. 1998).

ANTERIOR UVEITIS, CATARACTS, AND GLAUCOMA Anterior uveitis (inflammation of the iris and ciliary body) produces a variety of changes within the eye. These include decreased production of aqueous humor (decreased intraocular pressure), increased protein content of aqueous humor (flare), and accumulation of leukocytes (hypopyon) or erythrocytes (hyphema). Constriction of the pupil is an important diagnostic sign, as is photophobia because of painful inflammation of the ciliary muscle. Organophosphate toxicity, which is also accompanied by miosis, is an important differential. Miosis has also been reported with urea poisoning (Schmidt 1973). Adhesions may form between the swollen iris and the lens or cornea. Retinal detachment and glaucoma are other potential sequelae. Causes of Anterior Uveitis Septicemia Hypopyon, deep neovascularization of the cornea, and other signs of anterior uveitis sometimes accompany neonatal septicemia. The posterior segment of the eye or the brain may also be infected. Appropriate

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systemic antibiotic therapy is critical to survival of the animal. If the infectious agent is resistant to the antibiotic chosen, the corticosteroids used to treat the secondary anterior uveitis may exacerbate the primary infection.

thiamine whenever blindness is accompanied by any other neurologic signs rather than to exclude from consideration a common disease based on the presence of an unusual sign.

Toxemia

Even though the exact cause is rarely determined, in the absence of fluorescein uptake by the cornea, treatment of the eyeball showing such signs should include corticosteroids and atropine. The corticosteroids are generally given by bulbar subconjunctival injection with a tuberculin syringe and a 25-gauge needle. The atropine might be given by injection, but more commonly, ointment or drops are instilled every few hours until the pupil dilates, then once or twice a day. Both painful spasm of the ciliary muscle and the danger of adhesion formation are decreased by using atropine. The animal should be allowed access to a darkened stall until the ability to constrict the pupil is regained after discontinuation of therapy. Antiprostaglandin therapy also results in dilation of the pupil.

Constriction of the pupil and anterior uveitis may be noted in goats with severe toxic mastitis or metritis. Deep Keratitis Severe keratitis resulting from infectious keratoconjunctivitis or exposure keratitis may extend to or cause reflex inflammation of deeper portions of the globe. Mycoplasma spp. infections can also reach the uveal tract by the systemic route during septicemia (Whitley and Albert 1984). Retroviral Infections A nonsuppurative chorio-iridocyclitis, sometimes accompanied by granuloma formation, has been documented in the eyes of goats with chronic neurologic disease believed in retrospect to be caused by retroviral infection (Stavrou et al. 1969; Dahme et al. 1973). Clinical signs directly related to the ocular system included corneal opacity, nystagmus, and blindness (usually unilateral). The prevalence of anterior uveitis in goats with caprine arthritis encephalitis or related virus infections (see Chapter 5) is unknown. Clinical blindness could be the result of a brain lesion rather than an eye lesion and few studies have reported histology of the eye. In one group of naturally infected goats where optic nerves and eyes were examined, no histologic lesions were found in these tissues (Sundquist et al. 1981). Toxoplasmosis At least in other species, toxoplasmosis can lead to iridocyclitis and necrotizing granulomas on the retina and ciliary body. In one study including sheep (but no goats), granulomatous ocular lesions were demonstrated in eyes from twelve of eighteen sheep with experimental toxoplasmosis (Piper et al. 1970). Systemic therapy with sulfonamides and pyrimethamine and topical treatment with atropine, steroids, and 10% sulfacetamide ophthalmic ointment have been recommended. The possible occurrence of ocular lesions in kids congenitally infected with toxoplasmosis needs to be investigated. Trauma Blunt trauma to the head may induce hyphema or an anterior uveitis. This might explain the occasional occurrence of fibrin tags attached to the iris of goats with central blindness because of polioencephalomalacia (Smith 1979). In general, it is wiser to administer

Treatment of Anterior Uveitis

Cataracts Cataracts are opacities of the lens or its capsule. Uveal pigment may be deposited on the anterior lens capsule. Fluid accumulation within the lens or denaturation of lens protein may hinder light transmission. A cataract can occur as a sequela to any severe anterior uveitis if not vigorously treated. Congenital cataracts have apparently not been reported in goats (Wyman 1983). Referral to a specialist should precede any surgical attempt at cataract extraction. Glaucoma Secondary glaucoma has been reported as occurring after severe anterior uveitis induced by Mycoplasma agalactia (Moore and Whitley 1986). The intraocular pressure rises because the iridocorneal angle is closed by the inflammatory process. Both the anterior uveitis and the glaucoma may contribute to corneal edema, as does anterior lens luxation if it occurs. Buphthalmia (enlargement of the globe) may initially protect the retina. When intraocular pressure becomes high enough to damage the retina, permanent blindness occurs. Proper use of mydriatics and corticosteroids to prevent secondary glaucoma is paramount. Tonometry The only method available to most large animal practitioners for estimating intraocular pressure is digital tonometry. The index and middle fingers of one hand are used to slightly flatten the globe by applying pressure through the upper lid. The other hand simultaneously evaluates the second eye of the patient. At least until experience is gained, comparison with a normal goat is helpful.

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The Schiotz tonometer, although previously available in many small animal practices, is not practical for use in goats. The goat must be in dorsal recumbency for the cornea to be accessible when the tonometer is held vertically. A topical anesthetic is required. Struggling or compression of the jugular veins might artificially elevate the intraocular pressure. By contrast, Tono-Pen tonometers are easy to use on goats. Although a normal range for the goat using this device has not been reported, values from the patient could be compared with intraocular pressure measurements from several normal goats.

caused severe uveitis, chorioretinitis, and optic neuritis. Natural infection with bluetongue or use of an attenuated vaccine in ewes in the first half of pregnancy has caused necrotizing retinopathy in lambs, according to Wyman (1983). Toxoplasmosis, as discussed under anterior uveitis, can cause a granulomatous chorioretinitis in ruminants. These conditions apparently have not been reported in goats. Chorioretinopathy

It is unlikely that glaucoma will be diagnosed in an affected goat until the cornea is “steamy” and the globe is enlarging. In most instances, medical management is impractical. Prompt referral to an ophthalmic surgeon may be appropriate for certain valuable animals. Otherwise, the practitioner should plan to enucleate the glaucomatous eye when the goat appears to be in persistent pain or when the eyelids can no longer cover the enlarged globe well enough to prevent drying of the central cornea. An alternative to enucleation might be an injection of gentamicin plus corticosteroid into the vitreous to destroy the ciliary body.

This term suggests that active inflammation is not (or is no longer) present. One example would be scars from an earlier septicemia. Retinopathy is manifested by tapetal hyper-reflectivity and pale depigmented areas in the nontapetal fundus. Retinal atrophy has been reported after congenital infection with Akabane virus. A spontaneous retinopathy possibly caused by rod-cone dysplasia has been reported in a young Toggenburg goat (Buyukmihci 1980). Four other closely related Toggenburg kids in Canada were blind from birth and showed a similar tapetal hyperreflectivity and marked retinal vessel attenuation; an inherited disorder was suspected (Wolfer and Grahn 1991). Other causes of retinal degeneration in ruminants, even if unreported in goats, are mentioned below for completeness.

RETINAL CHANGES

Scrapie

A number of lesions may be recognized in the course of a thorough ophthalmoscopic examination of the retina. Cellular infiltration may appear focal or diffuse or it may follow blood vessels. Infiltrations are white or gray. Edema has a similar appearance but may be better demarcated. Hemorrhages have different shapes depending on the layer of the retina where they are located. Thus, focal or round hemorrhages are deep within the retina, linear lesions (flame hemorrhages) are in the nerve fiber layer, and crescent shaped (keel) hemorrhages are preretinal (beneath the vitreous).

Scrapie, at least in sheep, can cause a central blindness. However, multifocal retinal elevations have also been described. These are blister-like, hyperreflective, with a dark edge, and scattered in the tapetal fundus. They vary from one-fourth to three-fourths the size of the optic disc (Barnett and Palmer 1971).

Treatment

Papilledema Papilledema is a noninflammatory swelling of the optic disc. It is an important sign of increased intracranial pressure. Causes in ruminants include hypovitaminosis A, acquired and congenital hydrocephalus, space-occupying brain lesions, meningitis, encephalitis, coenurosis, and hexachlorophene toxicity (Whittaker et al. 1999). Papilledema is usually bilateral. The arterioles are more thread-like (and more red) than the congested retinal venules. Hemorrhages may be present on the disc or retina. Chorioretinitis Retinitis has been described in association with elaeophorosis in sheep. Trypanosomosis of sheep has

Border Disease Because of parallels with lesions identified in cattle affected in utero with bovine virus diarrhea (BVD) virus, border disease might be expected occasionally to be accompanied by retinal changes. Abnormalities reported in cattle include grayness of the optic disc, vascular attenuation, hyperreflective areas of the tapetal fundus, unusual admixtures of tapetal colors, and multifocal depigmentation of the nontapetal fundus. Cataracts may occur and normal pupillary light reflexes may be absent. Such findings have not yet been reported in sheep or goats. Bright Blindness Sheep consuming bracken fern (Pteridium spp.) (Barnett and Watson 1970) for many months may develop progressive bilateral blindness. The tapetum develops increased reflectivity, and the neuroepithelium degenerates. The pupils become circular and react poorly to light. The arteries and veins of the

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retina appear narrower than normal. The shepherd notices the blindness when a sheep becomes separated from the flock and runs around with elevated head and a high-stepping gait. Blind Grass Stypandra imbricata, or blind grass, is a plant found in western Australia. Goats and sheep that survive acute exposure become permanently blind, with degeneration of photoreceptor cells, optic nerves, and optic tracts. Clinical examination several weeks after blindness develops reveals foci of pigment epithelium hypertrophy, especially prominent in the nontapetal fundus near the optic disc. Pupillary light reflexes are absent (Main et al. 1981). A related Australian plant, Stypandra glauca (nodding blue lily), has been associated with blindness in goats consuming the plant during its flowering stage. Acute cerebral edema with subsequent compression of the optic nerve within the optic canal may be important to pathogenesis (Whittington et al. 1988). Other Plant Toxicities Helichrysum argyrosphaerum toxicity has caused papilledema and retinal changes in sheep and cattle in Namibia, with spongiform lesions occurring in brain and optic fasciculi as well (Kellerman et al. 2005). Goats appear to be resistant (Basson et al. 1975) but in one blind goat with cerebral and brainstem vacuolation, a slight increase in tapetal reflectivity and pigmented foci in the nontapetal fundus were noted (Van der Lugt et al. 1996). Some species of Astragalus (locoweed) cause a retinal degeneration, at least in cattle and sheep. Many cells in the body are vacuolated, including neurons in the brain and inner ganglionic layer of the retina and secretory cells in the lacrimal gland. The eye appears dull and vision is impaired (Van Kampen and James 1971). Swainsona (darling pea) in Australia causes similar signs. Both plants contain substances that inhibit lysosomal mannosidase, thereby producing a storage disease. Similar vacuolation of retinal cells has been seen in goat kids with hereditary beta mannosidosis (Render et al. 1989). Astragalus species have also caused blindness, ataxia, and weight loss (blind staggers) caused by high concentrations of selenium (Hosseinion et al. 1972), although it has been speculated that some cases of blind staggers were actually sulfurrelated polioencephalomalacia (Whittaker et al. 1999). This condition is discussed in Chapter 5. Dryopteris filix-mas (male fern) ingestion in cattle causes acute retrobulbar neuropathy that may progress to optic atrophy. Hemorrhages on or around the optic disc and papilledema are noted acutely. Chronic lesions include optic nerve atrophy and reduced retinal vasculature; these animals are blind.

Retinal Detachment Detachment occurs when transudates or exudates accumulate between the retinal pigment epithelium and the receptor layers. A total detachment results in blindness and is recognized by the presence of a billowing structure containing blood vessels in the vitreous. Case reports in goats are lacking.

AMAUROSIS Amaurosis is blindness without any externally detectable defect in the visual system. The cornea, lens, and uveal tract appear to be normal. If the lesion is limited to the cerebral cortex and optic nerve and nuclei are intact, the pupillary reflexes are also normal. Blindness becomes apparent because of abnormal behavior or failure to respond to visual stimuli. Blindness versus Failure to Blink It is common but inaccurate to equate the ability to blink in response to a menacing hand gesture with the ability to see; this is because the entire visual pathway, from the retina to the cerebral cortex, must be intact for the reflex to function (deLahunta 1983). Because it is a learned response, very young kids may not menace even though they have no trouble seeing and following a moving bottle or other item of interest. A goat with normal vision also fails to blink if facial nerve paralysis is present. This possibility is investigated by actually touching the medial or lateral canthus. Even a blind animal should then blink, unless either sensory or motor function is disturbed. Blindness versus Severe Depression or Toxemia Severely obtunded or semi-comatose goats respond minimally to stimuli routinely applied to evaluate cranial nerve function. If the animal is severely depressed, a metabolic disease (hypoglycemia, hypocalcemia, pregnancy toxemia, rumen acidosis), liver disease (see Chapter 11), or terminal septicemic or toxemic (Boermans et al. 1988) condition, rather than a lesion specifically involving visual pathways or cerebral cortex, may be present. It is inappropriate, then, to limit diagnostic consideration to those diseases with blindness as a leading sign. Polioencephalomalacia Blindness is almost always present in advanced cases of polioencephalomalacia. Thus, thiamine administration, as discussed in Chapter 5, is indicated (at least initially) for every goat with amaurosis. Enterotoxemia Blindness is one sign of focal symmetrical encephalomalacia, an uncommon disease reportedly caused by exotoxins of Clostridium perfringens, in sheep. The

270 Goat Medicine

condition has been reported only rarely in goats (see Chapter 5).

Although blindness is a prominent sign of lead poisoning in cattle, this is not the case in goats. Anorexia and diarrhea, not blindness and convulsions, are reported with experimental lead poisoning in goats (Davis et al. 1976).

the cerebral lesion. Pupillary reflexes generally remain normal, but papilledema may be noted because of increased intracranial pressure (Sharma and Tyagi 1975). In some cases, the skull overlying the cyst is softened and deformed, and pressure on the affected bone elicits signs of pain (loud bleating). Vision usually returns within one day after surgical removal of the cyst. The disease has not been reported in recent years in the United States (Kimberling 1988).

Hydrocephalus

Miscellaneous Causes of Central Blindness

A young kid that has a good suckle reflex and a normal gait may become separated from its dam or stuck in corners. Hydrocephalus or other congenital malformation of the brain may be responsible for this abnormal behavior associated with blindness. Sometimes the skull is domed, which increases the suspicion of hydrocephalus. Other kids have no outward conformational changes even though very little brain is in fact present.

Several other diseases may cause blindness in sheep, and perhaps in goats. Melioidosis is a fatal septicemic disease caused by Burkholderia (Pseudomonas) pseudomallei and occurs mainly in Southeast Asia and Australia. A central blindness can accompany other neurologic signs. Likewise, scrapie can cause blindness but will probably be recognized by other neurologic signs. Caprine arthritis encephalitis can cause a variety of central neurologic signs, including blindness. Chronic poisoning with some forms of arsenic, in some species, can cause blindness. Acute blindness in cattle and sheep has been associated with consumption of rape (Brassica napus), but documentation is meager. In some instances of poisoning with Brassica spp., the actual cause of blindness may be polioencephalomalacia (Wikse et al. 1987). Ironwood (Erythrophloeum chlorostachys), a tree from tropical Australia, has been reported to poison goats and cause, among other signs, a staring-eyed demeanor with vision apparently affected (Hall 1964). Overdosage with hexachlorophene, rafoxanide, and closantel can cause degeneration of the optic nerve, optic tract, or retina (Button et al. 1987). The pathologic changes (Gill et al. 1999) resemble those caused by Stypandra spp, but pigment epithelium hypertrophy has not been described.

Lead Poisoning

Vitamin A Deficiency Maternal deficiency of vitamin A produces atrophy of the optic nerves in calves. This is because the optic canals have not grown to accommodate the optic nerves, resulting in pressure atrophy and demyelination of the nerves. In the case of acquired avitaminosis A in cattle, there is an initial, often reversible night blindness caused by deficient formation of rhodopsin. If the deficiency continues, the retina degenerates and eventually constriction of the optic nerve can occur in growing calves. Papilledema is an important sign of vitamin A deficiency and is secondary to increased cerebrospinal fluid (CSF) pressure. Vascular congestion and focal superficial hemorrhages also occur. The intraocular pressure is not elevated. Specific reports of this condition in goats are lacking, and in one experimental study adult goats fed a vitamin A depletion ration failed to develop papilledema or increased CSF pressure (Frier et al. 1974). Severe vitamin A deficiency, as occurs during the dry season or droughts in semiarid regions, causes night blindness that is not always accompanied by corneal opacity and ulceration. These ocular problems are documented in sheep (Eveleth et al. 1949, Ghanem and Farid 1982) and have been reproduced experimentally in goats (Schmidt 1941). Coenurosis Coenurus cerebralis is the larval stage of the tapeworm Taenia multiceps. It can form a cyst in the cerebral hemispheres or median fissure. A common clinical sign is partial or total blindness in one eye (Sharma 1965; Tirgari et al. 1987; Nooruddin et al. 1996). The head is held in the direction away from the blind eye and the animal circles in that direction, that is, toward

Residual Blindness Blindness may persist for days, weeks, or even the life of a goat that did not receive thiamine early in the course of polioencephalomalacia. Other traumatic or metabolic insults to the cerebral cortex (prolonged application of a disbudding iron, pregnancy toxemia) could also result in amaurosis. Usually there is a history of partial recovery from a previous severe illness.

ENUCLEATION Enucleation is indicated if the eyeball has collapsed because of trauma or the perforation of an ulcer resulting from infectious keratoconjunctivitis, or whenever a chronic painful eye condition cannot be resolved. Whether local or general anesthesia is used depends on the facilities available to the veterinarian. If necessary, tranquilization with xylazine and infiltration of 1% lidocaine subcutaneously around the eye and in the depth of the orbit can be used. Thus, in a large animal

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practice, enucleation in a goat can be performed on the farm. The lids are clipped and disinfected; irritating solutions should be kept out of the unaffected eye, and they should not be allowed to pool on the surgery table near the down eye. The lid margins, conjunctival sac, and ocular muscles are dissected free from the orbit with curved scissors. A tight ligature around the optic nerve and accompanying blood vessels should control hemorrhage, although a hematoma may form in the orbit. An everting mattress suture is often chosen to close the skin, and penicillin may be instilled into the cavity created by enucleation.

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7 Blood, Lymph, and Immune Systems Basic Caprine Hematology 275 Anatomic Considerations 275 Bone Marrow 275 Blood and Plasma Parameters 276 Erythrocyte Parameters 276 Hemoglobin 276 Response to Anemia 278 Blood Types 278 Transfusions 278 Leukocyte Parameters 279 Interpretation of Leukogram 279 Platelet Parameters 280 Coagulation Parameters 280 Basic Caprine Immunology 280 Immunoglobulins 280 Other Serum Proteins 281 Cell-mediated Immune System 281 Cytokines 282 Major Histocompatibility Complex (MHC) 283 Diagnosis of Hemic-Lymphatic Diseases by Presenting Sign 284 Bleeding Disorders 284 Anemia 284 Lymphadenopathy 287

Caprine hematology has received considerable attention in the past thirty years. A range of discrepant normal values and hematologic responses have been reported. These discrepancies result from variations in age, breed, and health status of the goats evaluated and from differences in environment, climate, methodology, and sample size. Despite inconsistencies, sufficient data exists for reasonable standardization of normal caprine hematologic values and kinetics (Jain 1986; Kramer 2000). In contrast, information on the organization of the caprine immune system and the immune response is limited. Newer information that is available derives from studies of specific diseases. The most notable is caprine arthritis encephalitis (CAE), which emerged as an animal model for study of acquired immunodeficiency syndrome (AIDS) in humans because of the relatedness of the CAE and human immunodeficiency (HIV) lentiviruses (Cheevers et al. 1997; Sharmila et al. 2002; Fluri et al. 2006; Bouzar et al. 2007) as well as paratuberculosis (Storset et al. 2000, 2001) and others. Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Specific Diseases of the Hemic-Lymphatic System 287 Rickettsial Diseases 287 Anaplasmosis 287 Eperythrozoonosis 288 Tick-borne Fever 289 Bacterial Diseases 290 Leptospirosis 290 Anthrax 293 Protozoal Diseases 293 Babesiosis 293 Theileriosis 295 Trypanosomosis 296 Toxicological Diseases 302 Copper Poisoning 302 Kale Anemia (Brassica Poisoning) 305 Other Plant-related Anemias 306 Diseases of the Immune System 306 Thymoma 306 Failure of Passive Transfer (FPT) of Maternal Immunity 307 References 311

BASIC CAPRINE HEMATOLOGY Anatomic Considerations The principal organ of hematopoiesis in the goat is the bone marrow. The spleen of the goat is located in the left craniodorsal abdomen between the diaphragm and the dorsal sac of the rumen. The anomaly of two distinct spleens in the left abdomen of a goat has been reported (Ramakrishna et al. 1981). As in other ruminants, goats possess a hemal node system. These nodes contain lymphoid tissue and may also participate in blood storage by hemoconcentration. There are five to twelve hemal nodes in a goat, located along the course of the aorta in the abdominal and thoracic cavities (Ezeasor and Singh 1988). The distribution of the lymph nodes is discussed in more detail in Chapter 3. Bone Marrow The myeloid to erythroid (M:E) ratio of the bone marrow of the goat has been reported as 0.69, 275

276 Goat Medicine

indicating more active erythrocyte than granulocyte production. The proportions of cell types found in normal caprine marrow is reported as follows: myeloblasts, 0.58%; promyelocytes, 0.79%; neutrophilic myelocytes, 2.69%; metamyelocytes, 8.25%; band neutrophils, 8.88%; segmented neutrophils, 9.98%; eosinophils, 1.79%; basophils, 0.06%; monocytes, 0.02%; lymphocytes, 7.49%; and nucleated erythrocytes, 56.33% (Coles 1986). Megakaryocytes were not included in the differential count. Bone marrow collection procedures should be performed aseptically. Bone marrow biopsies and aspirates can be conveniently obtained from the iliac crest. In addition, an aspirate can be obtained from the dorsal 5 to 10 cm of ribs 10 to 13 using sturdy, 3.8-cm, 16- or 18-gauge styletted needles (Weber 1969). Care must be taken to place the needle on the midline of the narrow goat rib. Marrow aspiration from the third or fourth sternebrae also has been reported (Whitelaw 1985). Because goats are prone to developing chronic abscesses in the sternal region, the sternal site should be used as a last resort. Blood and Plasma Parameters Mean blood volume as a percentage of body weight is approximately 7% with a range of 5.7% to 9% (Fletcher et al. 1964; Brooks et al. 1984), or 70 to 85.9 ml/ kg of bw (Jain 1986). Blood volume increases in response to increased altitude (Bianca 1969). The mean specific gravity of whole blood is 1.042 with a range of 1.036 to 1.050 (Fletcher et al. 1964; Brooks et al. 1984). The osmotic pressure of serum colloids is 300 mm H2O. Mean plasma volumes range from 4.2% to 7.5% of body weight, or 53 to 60.2 ml/kg of bw (Jain 1986). Mean plasma specific gravity is 1.022, with a range of 1.018 to 1.026. Erythrocyte Parameters Erythrocyte parameters in the goat are labile, changing markedly over the goat’s lifetime (Holman and Dew 1964, 1965; Edjtehadi 1978). So-called normal or average values from the clinical laboratory, then, must be interpreted in the context of the animal’s age. The decreases in hemoglobin (Hb) and packed cell volume (PCV) that occur during the first month of life may be due to iron deficiency anemia associated with a milk diet. The decrease can be prevented in kids by administering 150 mg of iron as iron dextran at birth (Holman and Dew 1966). Other age-related variations seen in erythrocyte parameters are shown in Table 7.1. Seasonal changes are also noted in erythrocyte parameters, with greater red blood cell (RBC), Hb, and PCV values in late summer and fall than in winter and spring. Male goats tend to have higher RBC counts than females. Pregnancy has little effect on erythrocyte

parameters, but PCV can decrease during the first five months of lactation. The goat has the smallest erythrocyte of the domestic mammals, with a diameter of 3.2 to 4.2 microns. As a result, standard methods of determining the PCV may overestimate it by as much as 10% to 15% because of inadequate centrifugation time. For the microhematocrit method, centrifugation for a minimum of ten minutes at 14,000 G is recommended for accurate results. The standard Wintrobe method cannot generate sufficient relative centrifugal force to completely pack goat RBCs, even when centrifugation time is extended. As much as 20% of plasma can be trapped with the erythrocytes (Jain 1986). The standard erythrocyte sedimentation rate (ESR) is not applicable to the goat because there is no settling of goat RBCs within the one-hour interval prescribed for the Wintrobe method. However, a decrease of 2 to 2.5 mm can be observed in normal goat blood held for twenty-four hours. The small size of the goat RBC is also associated with the highest osmotic fragility among the domestic species. When exposed to hypotonic saline solutions, RBC hemolysis begins at concentrations of 0.62% to 0.74% and complete hemolysis occurs in saline concentrations of 0.48% to 0.60%. Pygmy goat erythrocytes are more fragile than those of Toggenburg goats on the basis of susceptibility to osmotic lysis, possibly because of differences in membrane composition (Fairley et al. 1988). Goat RBCs have only slight biconcavity. In blood smears, they lack a zone of central pallor and do not exhibit rouleaux formation, except perhaps at the edge of a thick smear. Normal cell shape is quite variable and poikilocytosis is common, with triangular, rodshaped, pear-shaped, and elliptical cells frequently seen, especially in goats younger than three months of age. Sickle cells can occur in Angora goats similar to those seen in deer (Jain et al. 1980). This morphologic change is associated with filamentous polymerization of hemoglobin and is considered innocuous. Nucleated RBCs may be seen in newborn goats as old as six weeks of age, but are uncommon afterwards. Reticulocytes are always absent or rare in health. Basophilic stippling of goat erythrocytes has been reported in experimental lead poisoning (Davis et al. 1976). The normal life span of circulating RBCs in the domestic goat, Capra hircus, is an average of 125 days, but as long as 165 days in a wild goat, the Himalayan Tahr (Hemitragus jemlaicus) (Kaneko and Cornelius 1962). Hemoglobin The goat has one embryonic Hb type that occurs very early in fetal development in erythroid precursors. A single distinct fetal Hb (HbF) that comprises alpha and gamma globin chains is present by approxi-

7/Blood, Lymph, and Immune Systems 277 Table 7.1. Erythrocyte parameters in the normal goat from selected reports worldwide. Country

Goat description

RBC count (¥ 106 ul)

PCV (%)

Hb (g/dl)

MCV (fl)

MCH (pg)

MCHC (%)

References

India

0–6 months old

16.3

27.9

8.0

17.2

28.8

6–12 months old 1–2 years old 2–3 years old 3–4 years old 4–5 years old 5 years and older 0–6 months old 6–12 months old 12–24 months old 2 years old All females Pregnant females All males All goats Adult males

13.6 12.8 12.6 10.3 12.2 12.8 13.4 ± 3.3 12.9 ± 2.1 11.9 ± 1.7 11.8 ± 2.3 12.2 ± 2.2 11.3 ± 2.0 12.7 ± 2.7 12.3 ± 2.4 14.95 ± 2.40

24.3 22.6 25.5 21.9 24.3 26.0 25.1 ± 3.4 27.0 ± 4.6 26.9 ± 3.8 25.9 ± 4.4 26.1 ± 4.5 26.9 ± 4.0 25.9 ± 3.9 26.1 ± 4.1 27.2 ± 5.2

7.0 7.4 7.0 6.5 7.0 7.2 8.4 ± 0.9 9.1 ± 1.4 8.7 ± 1.3 8.5 ± 1.5 8.5 ± 1.3 8.7 ± 1.6 8.6 ± 1.3 8.6 ± 1.3 10.6 ± 1.6

17.6 18.0 20.5 22.2 20.0 21.0 19.8 ± 4.8 21.2 ± 3.4 22.9 ± 3.5 22.4 ± 4.4 21.8 ± 3.7 23.9 ± 3.6 21.3 ± 4.8 21.8 ± 4.4 18.1 ± 1.7

— — — — — — — — — — — — — — 7.2 ± 0.8

28.3 32.6 27.3 29.3 29.0 27.9 33.9 ± 3.9 33.9 ± 3.3 32.4 ± 3.2 32.9 ± 3.6 33.0 ± 4.0 32.3 ± 0.9 33.5 ± 2.9 33.1 ± 3.4 39.5 ± 3.6

Adult wethers Adult females Adults

16.34 ± 2.10 13.94 ± 2.80 14.5 ± 2.9

34.8 ± 3.8 28.9 ± 5.1 34.0 ± 4.9

13.1 ± 1.2 11.4 ± 1.6 12.7 ± 1.5

21.4 ± 0.8 21.1 ± 3.1 23.3 ± 2.1

8.1 ± 0.5 8.4 ± 1.6 7.9 ± 0.4

37.7 ± 2.1 39.6 ± 4.4 34.4 ± 1.5

Nangia et al. 1968 ″ ″ ″ ″ ″ ″ Oduye 1976 ″ ″ ″ ″ ″ ″ ″ Wilkins and Hodges 1962 ″ ″ Lewis 1976

Nigeria

United Kingdom

United States

RBC = red blood cell, PCV = packed cell volume, Hb = hemoglobin, MCV = mean corpuscular volume, MCH = mean corpuscular hemoglobin, MCHC = mean corpuscular hemoglobin concentration.

mately forty days of fetal life and persists through birth, diminishing to zero by approximately fifty days of age. Replacing HbF in the young growing goat is HbC, a Hb type peculiar to sheep, goats, and other members of the Caprini family, including the aoudad, Barbary sheep, and the mouflon. In the goat, by fifty days of age, from 80% to 100% of Hb is the HbC type. Hemoglobin C demonstrates decreased oxygen affinity compared with HbF. It is postulated that HbC is a physiologic adaptation that allows the relatively fastgrowing kid to satisfactorily oxygenate tissues during rapid growth (Huisman et al. 1969). The marked poikilocytosis commonly observed in kids between one and three months of age may be associated with the switch to HbC during this period. By 120 days, the final adult types of Hb, comprised of alpha globin chains together with beta globin chains, have largely replaced HbC. However, 5% to 10% of adult Hb may normally persist in the HbC form. In addition to its regular occurrence in growing kids, and its mild persistence in normal adults, Hb switching to HbC also occurs extensively in adult goats during erythropoiesis in response to naturally occurring and experimentally induced anemias and at high altitudes.

Erythropoietin is the direct stimulus for Hb switching and the increased production of HbC by developing erythrocytes in the bone marrow (Garrick 1983). In addition to small amounts of HbC, three adult hemoglobins are commonly recognized and identified as A, B, and D, although a later publication identified the three adult hemoglobins as A, D, and E (Garrick and Garrick 1983). Adult hemoglobins are comprised of both alpha and beta chains and globin chain production is controlled by at least five structural genes. Polymorphism of goat Hb occurs from variation in either beta or alpha chains. Phenotypic variation occurs in the goat with phenotypes AA, AB, BB, and AD previously reported as most common (Huisman 1974). Another Hb type, HbDmalta has been identified in high frequency in goats on Malta (Bannister et al. 1979). An association between certain Hb phenotypes and disease resistance has been observed in the goat in relation to helminthiasis (Buvanendran et al. 1981). In a Finnish study of milking goats, increased hemoglobin concentration correlated with increased milk yields and decreased somatic cell counts, though there was no direct explanation for the relationship (Atroshi et al. 1986).

278 Goat Medicine

Response to Anemia The goat demonstrates only a mild to moderate reticulocyte response to anemia. Red cell parameters have been measured after experimental induction of hemorrhagic anemia via controlled venisection that reduced mean RBC counts more than 50% (Dorr et al. 1986). Reticulocyte counts before bleeding were between 0% and 0.5%. Maximum reticulocyte counts occurred six to eight days after bleeding, and ranged from 3.2% to 7.7%. A second reticulocyte peak was seen between eleven and nineteen days with maximum counts between 2.9% and 6.3%. Anisocytosis and persistence of macrocytes for four weeks after bleeding were more dramatic indicators of regeneration than reticulocytosis. The large size of newly released erythrocytes was reflected in a progressive increase in the mean corpuscular volume (MCV), which was highest from twenty-five to twenty-nine days after bleeding, but did not always exceed the normal range of MCV reported for the species. Therefore, the MCV must be interpreted carefully in establishing the presence of regenerative anemia. Hemoglobin and PCV levels returned to before-bleeding levels by five weeks. Jain et al. (1980) reported a marked poikilocytosis in response to experimentally induced hemorrhagic anemia in normal Angora goats exhibiting increased percentages of erythrocyte sickling. The percentage of fusiform (sickle) cells decreased as new distinct poikilocytic forms developed. Poikilocytosis was maximal between eight and thirteen weeks after bleeding. The change in erythrocyte morphology was attributed to the presence of HbC in regenerative cells. Blood Types Currently, most references to the caprine blood grouping system compare it to the sheep system but specific similarities and differences are not always clear. Seven blood groups are known to exist in the sheep, identified as R-O, A, B, C, D, M, and X. The antigens of the R-O group are soluble substances, and naturally occurring anti-R antibodies may be found in R-negative sheep. The M system in the sheep is associated with variation in intracellular RBC potassium concentration, with animals homozygous for the Ma allele having greater intracellular potassium levels. High potassium and low potassium red cell types have also been recorded in goats, but no clear association with the M blood group system has been established despite attempts to do so (Ellory and Tucker 1983). The B system is most complex, with at least fifty-two alleles involved in expression of B-group antigens. Using sheep reagents, at least five of the seven sheep blood groups have been confirmed in goats; B, C, M, R-O, and X. Multiple phenogroups occurred in the B system, similar to sheep (Nguyen 1977).

As with other ruminant species, hemolytic testing is preferred to agglutination testing for blood typing work because of the inherent inagglutinability of erythrocytes in some individuals (Andresen 1984). Neonatal isoerythrolysis is not known in goats. However, hemolytic disease has been reported in oneweek-old kids that had received bovine colostrum at birth (Perrin et al. 1988). In 1992, the American Dairy Goat Association (ADGA) instituted a voluntary blood typing program to assist in indentification and parentage verification of registered goats. In 1998, ADGA replaced identification of individual goats and parentage by blood typing with DNA typing because of the superiority of DNA technology and the limited availability of antisera available for blood typing (Bowen 2007). Transfusions In sheep, it has been advised that R-positive blood not be used for transfusion to avoid early donor RBC destruction by isoantibodies (Andresen 1984). In practice, however, cross-matching of goat or sheep blood before single transfusions is not usually performed (Bennett 1983). Nevertheless, naturally occurring antibodies to RBCs can be present in goats and cross matching may be advisable. Transfusion reaction rates of 2% to 3% have been reported (Fletcher et al. 1964). Cross matching is indicated whenever multiple transfusions are anticipated. Autologously transfused RBCs have a half survival time of eight days while homologously transfused cells have a half survival time of only 2.4 to 5.1 days (Gulliani et al. 1975). Sheep RBCs transfused into goats had a maximum average life span of 4.6 days (Clark and Kiesel 1963). Cross species transfusions in clinical practice are not advised. Goats are considered to be a “large-spleened” domestic species. As such, the healthy goat can accommodate a blood loss of up to 25% of the red cell mass acutely, and up to a 50% loss over a twenty-four-hour period. In such cases, fluid replacement is of more concern than RBC replacement. In chronic blood loss, as often occurs with parasitic diseases, the PCV may reach levels as low as 9% without overt clinical manifestations of anemia, as long as the animal is not decompensated by stress, activity, or concurrent disease. Treatment of the underlying cause of anemia may be sufficient therapy without the need for blood transfusion. If the anemia is accompanied by profound hypoproteinemia with clinical signs of edema and ascites, plasma transfusions may be indicated. For transfusions, the safe volume of blood that can be collected from a healthy goat has been reported as low as 6 ml/kg (Mitruka and Rawnsley 1981) to as high as 15 ml/kg bw (Bennett 1983). In practice, 10 ml/ kg of bw is a reasonable volume. A 4% solution of

7/Blood, Lymph, and Immune Systems 279

sodium citrate is a suitable anticoagulant for blood collection, using 50 to 100 ml per 400 ml of blood collected. Collection bags or bottles should be swirled continuously during blood collection, and blood administered through a filtered system to remove possible clots. Blood can be safely given to recipients in volumes of 10 to 20 ml/kg bw. Leukocyte Parameters The mean white blood cell (WBC) count of the goat is generally reported to be 9,000 cells/ul with a range of 4,000 to 14,000. However, total WBC counts and differential cell counts may vary significantly with age as shown in Table 7.2. This is also true of the neutrophil to lymphocyte (N:L) ratio. The following mean N:L ratios have been reported for normal goats at different ages: one day old, 1.6 : 1; one week old, 0.8 : 1; one month old, 0.6 : 1; three months old, 0.3 : 1; two years of age, 1.1 : 1; and three years of age and older, 1.0 : 1 (Holman and Dew 1965a). These changes are partially due to a lower neutrophil count at birth that peaks at one month of age and then returns to and remains at birth levels after three months of age. More significant is the dramatic two- to three-fold increase in lymphocyte numbers that occurs from birth to three months of age. Lymphocyte numbers begin to

decline again and remain roughly equivalent to neutrophil numbers throughout adulthood. Eosinophils, basophils, and monocyte counts did not change notably with age in this study (Holman and Dew 1965a). However, in a field study with samplings of 1,000 goats in Mexico, eosinophil counts in kids younger than seven weeks of age averaged 0.5% of the WBC count, but 4.3% in adults (Earl and Carranza 1980). Band neutrophils may represent up to 2.5% of the neutrophils in neonates as old as six weeks of age, but are rare or absent in health after this time. Lymphocytes in goats exhibit three distinct sizes: small, medium, and large. Young goats may exhibit two and a half times more small lymphocytes than large. It is postulated that the small lymphocytes represent thymocytes and that small lymphocyte numbers decrease as thymic involution progresses (Earl and Carranza 1980). Morphologically, large lymphocytes may be confused with monocytes. The large lymphocyte is distinguished by a nuclear chromatin that is condensed in large, irregularly shaped clumps, as compared with the looser, stringier chromatin pattern of monocytes. Interpretation of Leukogram Guidelines for interpretation of caprine leukograms have been suggested (Coles 1986). A WBC count more

Table 7.2. Total leukocyte numbers and differential counts in normal goats reported worldwide. Country/ reference

Goat description

WBC count (×103/ul)

Mature neutrophils (%)

Band neutrophils (%)

Lymphocytes (%)

Monocytes (%)

Eosinophils (%)

Basophils (%)

References

Mexico

2 days–7 weeks old Adults First day of life

33.66 ± 12.56

0.90 ± 0.95

64.07 ± 13.00

0.82 ± 0.91

0.52 ± 0.72

0.03 ± 0.18

— 7.52 ± 2.94

50.28 ± 13.73 55.2 ± 17.9

0.19 ± 0.43 —

43.43 ± 13.94 41.3 ± 14.9

1.24 ± 1.11 2.0 ± 1.3

4.27 ± 2.07 0.7

0.60 ± 0.77 0.2

8.90 ± 4.14

42.9 ± 11.8

52.4 ± 11.9

2.6 ± 1.2

0.2

0.5

Earl and Carranza 1980 ″ Holman and Dew 1965 ″

9.24 ± 2.42

32.7 ± 10.8

62.5 ± 9.4

2.1 ± 1.7

1.0

1.1

18.18 ± 3.84

22.5 ± 5.8

72.6 ± 11.5

2.0 ± 3.7

1.1

0.4

8.08 ± 2.51

49.0 ± 10.7

42.3 ± 10.4

3.1 ± 2.5

1.9

0.9

9.73 ± 2.51

47.7 ± 12.2

48.2 ± 12.0

2.2 ± 1.0

1.5

0.2

13.30 ± 2.70

43.0 ± 6.7

51.0 ± 11.4

2.0

1.0

Lewis 1976

United Kingdom

United States

1 week old 1 month old 3 months old 2 years old 3 years old and older Adults

WBC = white blood cell.

3.0

280 Goat Medicine

than 13,000/ul constitutes leukocytosis and a count less than 4,000/ul, leukopenia. A neutrophil count greater than 7,200/ul represents neutrophilia and a count less than 1,200/ul, neutropenia. More than 100 band neutrophils/ul constitutes a left shift. Lymphocytosis is interpreted as a lymphocyte count greater than 9,000/ul and lymphopenia by a count less than 2,000/ul. Monocytosis is represented by a monocyte count more than 550/ul and eosinophilia by an eosinophil count more than 650/ul. Inflammatory responses in the goat often produce a neutrophilia with total WBC counts in the range of 22,000 to 27,000/ul. The maximum WBC count reported in a goat is 36,300/ul observed in association with a kidney abscess (Jain 1986). A mature neutrophilia is often seen that in association with stress and chronic infections, particularly when abscesses develop as in caseous lymphadenitis or mastitis. Acute bacterial infections can produce a moderate to severe neutrophilia with some degree of left shift. Acute, severe coccidiosis in young kids is a frequent cause of marked neutrophilia and left shift. Leukopenia is a common finding in infectious conditions of goats associated with the release of endotoxin. Transient leukopenia has been reported with experimental administration of staphylococcal enterotoxin B and E. coli endotoxin (Van miert et al. 1986). Leukopenia also occurs in theileriosis and tick-borne fever. Infection of WBCs is a fundamental part of the pathogenesis of these diseases. In theileriosis, lysis of lymphocytes occurs when protozoal merozoites are released into the bloodstream and lymphopenia may be observed. In tick-borne fever, Ehrlichia phagocytophilia invade the cytoplasm of granulocytes and monocytes, producing a marked leukopenia. Persistent leukopenia also has been reported in experimental heartwater disease (cowdriosis) (Illemobade and Blotkamp 1978) and as a result of plant poisoning with Ipomoea carnea in goats in the Sudan (Tartour et al. 1974). Neoplastic transformation of lymphocytes may occur in caprine lymphosarcoma. This condition is not common in goats, and leukemia is a rare clinical presentation when the disease does occur. Peripheral lymphadenopathy is the clinical presentation most likely to suggest the diagnosis of lymphosarcoma in goats. Platelet Parameters The mean platelet count in the goat is generally considered to be 500,000/ul, with a range of 340,000 to 600,000/ul (Lewis 1976; Mitruka and Rawnsley 1981). One disparate study identified considerably lower counts in goats, with an average count of 116,000/ul

during the first two weeks of life, decreasing to 28,000/ ul by 1.5 years of age and stabilizing at an average of 62,550/ul by two years of age (Holman and Dew 1965a). These findings have not been duplicated by others. Platelets appear in the peripheral blood, usually in clusters of varying size. The platelets themselves also vary in size and shape, but all contain prominent azurophilic granules that are evenly distributed throughout the cytoplasm. Coagulation Parameters Two studies of coagulation parameters in the goat have been reported (Breukink et al. 1972; Lewis 1976). Both general coagulation tests and specific coagulation factor assays were conducted. Reported values are summarized in Table 7.3.

BASIC CAPRINE IMMUNOLOGY The area of veterinary immunology has made considerable advances in recent years, but specific information on the caprine immune system remains relatively difficult to find in comparison to other domestic animal species. The purpose of this section is to highlight what is specifically known about the caprine immune system. A broader view of veterinary immunology is available from textbooks on the subject (Tizard and Schubot 2004) There are no reported inherited immunodeficiencies in goats. Acquired immune-mediated diseases are uncommon and those that occur, such as the pemphigus complex, are discussed in the chapters relating to the organ system most affected. The most important immunological disease of goats is that shared with other ruminant species, namely, failure of passive transfer of immunologlobulins to the newborn via the dam’s colostrum. Failure of passive transfer (FPT) is discussed in detail later in this chapter. Immunoglobulins The structure and function of ruminant immunoglobulins have been reviewed and the categories and distribution of caprine immunoglobulins fit the general ruminant pattern (Butler 1986). The major classes of immunoglobulin identified in the goat are IgG, IgA, and IgM. As in cattle and sheep, there are two distinct IgG subclasses, IgG1 and IgG2 (Gray et al. 1969). The major immunoglobulin in goat colostrum is IgG1, and it is transported preferentially over IgG2 into the mammary gland from serum (Micusan and Borduas 1976). This is presumably because of a higher affinity of IgG1 for Fc receptors on mammary epithelial cells. IgG1 is also the predominant circulating serum antibody produced in response to infection (Micusan and Borduas 1977). Local IgG1 production has also been

7/Blood, Lymph, and Immune Systems 281 Table 7.3. Coagulation parameters reported from normal goats. Parameter

Units

Mean

Standard deviation

Range

Reference

Bleeding time Clotting time Lee-White; glass Clotting time Lee-White; plastic Clotting time capillary method Prothrombin time (PT)

Minutes Minutes

— 5.5

— ±0.5

Minutes

18.3

±4.5

1–5 5.0–6.1 1.0–5.0 12.3–23.0

Brooks et al. 1984 Lewis 1976 Brooks et al. 1984 Lewis 1976

1.0–5.0

Brooks et al. 1984

Russell viper venom time (RVV) Activated partial thromboplastin time (APTT) Thrombin time (TT) Fibrinogen

Seconds Seconds

Platelets/ul

Minutes Seconds

Seconds mg/dl

× 103

11.7 12.6 18.5 32.4 41.0 27.0 336 462 551 483

demonstrated in synovial fluid, specifically in response to caprine arthritis encephalitis (CAE) virus infection (Johnson et al. 1983). Very little is recorded about caprine IgM, possibly because little difference has been observed in the structure and function of IgM between ruminant species (Aalund 1972; Butler 1986). Caprine IgA has been isolated from serum, colostrum, milk, saliva, and urine. A distinct secretory component occurs in secretions, either in the free state or associated with IgA. The small amount of IgA found in serum is rarely associated with secretory component (Pahud and Mach 1970). IgA is considered the primary immunoglobulin of mucosal surfaces. In all the ruminants, including goats, immunoglobulins with biologic activities typical of IgE have been identified. IgE has become recognized as a useful marker for the development of parasite resistance in ruminant animals and efforts are underway to develop tests for the measurement of IgE to detect resistance. Partial DNA sequencing of caprine IgE has been reported as part of this overall effort (Griot-Wenk et al. 2000). Concentrations of caprine immunoglobulins in serum and various secretions are presented in Table 7.4. Other Serum Proteins The range of mean total serum protein concentrations reported in goats is from 6.75 to 7.53 gm/dl with concentrations in individual goats ranging from 5.9 to

±0.5

±1.3 ±7.5 ±5.0 ±66.1 ±92.9

9.0–14.0 11.2–12.3 10.6–14.8 17.2–19.4 28.4–37.6 34.0–61.0 20.9–33.4 100–400 268–435 340–632 378–656 308–628

Brooks et al. 1984 Lewis 1976 Breukink et al. 1972 Lewis 1976 Lewis 1976 Breukink et al. 1972 Lewis 1976 Brooks et al. 1984 Lewis 1976 Breukink et al. 1972 Lewis 1976 Breukink et al. 1972

8.3 gm/dl (Fletcher et al. 1964; Melby and Altman 1976; Mitruka and Rawnsley 1981). Concentrations for various serum proteins reported in goats are summarized in Table 7.5. The normal range of plasma fibrinogen levels in goats, 0.1 to 0.4 gm/dl, is less than that of cows. Hyperfibrinogenemia frequently occurs in conjunction with neutrophilia in inflammatory responses. The maximum goat plasma fibrinogen recorded during inflammation is 1.1 gm/dl (Jain 1986). Reports of complement component concentrations in goats are limited. However, one study demonstrates hemolytic, conglutinating, and bactericidal complement activity and indicates that complement activity is significantly less in kids younger than six months of age than in adults (Bhatnagar et al. 1988). Cell-mediated Immune System The induction of the host immune response begins at mucosal surfaces where immune cells in mucosaassociated lymphoid tissue (MALT) come into contact with and process antigens for subsequent transport to regional lymph nodes. The structure, function, and distribution of the caprine MALT system has been reviewed (Liebler-Tenorio and Pabst 2006). Distinct populations of B and T lymphocytes have been identified in goats (Sulochana et al. 1982) and subpopulations of T lymphocytes also have been identified on the basis of reactivity and nonreactivity to

282 Goat Medicine Table 7.4. Concentrations of immunoglobulin types in various body fluids of normal goats. Source

Total IgG (mg/ml ± S.D.)

IgG1 (mg/ml)

IgG2 (mg/ml)

First colostrum

53.27 ± 5.30

50.83 ± 4.95

2.27 ± 1.32

IgA (mg/ml)

IgM (mg/ml)

58.0 (50.0–64.0)

1.70 (0.90–2.40)

3.80 (1.60–5.20)

Mature milk

0.25 (0.10–0.40)

0.06 (0.03–0.09)

0.03 (0.01–0.04)

Normal adult serum

19.97 ± 1.55

0.32 (0.05–0.90)

1.60 (0.80–2.0)

10.92 ± 0.84

9.07 ± 0.78

22.0 (18.0–24.0) Kid serum 18 hours post suckling

73.59 ± 2.20

1 week old

29.12 ± 4.80

nm

4 weeks old

16.18 ± 1.25

1.71 ± 0.92

8 weeks old

11.92 ± 0.91

4.56 ± 0.84

12 weeks old

12.08 ± 0.35

8.32 ± 0.94

Adult saliva

0.10 (0.01–0.25)

0.20 (0.03–0.60)

t

Reference *Micusan and Borduas 1977 **Pahud and Mach 1970 **Pahud and Mach 1970 *Micusan and Borduas 1977 **Pahud and Mach 1970 ***Nandakumar and Rajagopalaraja 1983 ****Micusan et al. 1976 **** Micusan et al. 1976 ****Micusan et al. 1976 ****Micusan et al. 1976 **Pahud and Mach 1970

IgG = immunoglobin G, IgA = immunoglobin A, nm = not measurable, t = trace. * standard deviations, ** ranges, *** not reported if SE or SD; **** standard errors.

peanut agglutinin (PNA) (Banks and Greenlee 1982). The percentages of B cells and PNA-positive T cells among peripheral blood lymphocytes have been reported, respectively, as 14% and 69% (Banks and Greenlee 1982; Hedden et al. 1986). There are several reports on optimization, kinetics, and application of the in vitro lymphocyte transformation or blastogenesis assay for the measurement of lymphocyte responses using standard mitogens (Staples et al. 1981; Greenlee and Banks 1985), specific antigens, such as CAE virus (DeMartini et al. 1983), steroids (Staples et al. 1983), and allogeneic lymphocytes (van Dam et al. 1978). Normal caprine neutrophil function has been evaluated in female goats using a variety of indices including migration, chemotaxis, bacterial ingestion, cytochrome C reduction, and antibody-dependent, cell-mediated cytotoxicity (Maddux and Keeton 1987). The effect of dexamethasone and levamisole on neutrophil functions has also been reported (Maddux and Keeton 1987a). Selenium deficiency in goats has been shown to have adverse effects on caprine neutrophil function (Aziz et al. 1984). There is very little informa-

tion on characterization and function of caprine macrophages and nonneutrophil leukocytes. Cytokines Cytokines are proteins that play a central role as immune mediators during host responses against foreign pathogens. The role of cytokines in veterinary medicine has received considerable attention and a recent text on the subject has chapters on cattle, sheep, pigs, horses, dogs, cats, and birds, but alas, not on goats (Schijns and Horzinek 1997). Though knowledge on goat cytokines has not been comprehensively reviewed, information is available in various research reports. Interleukin 1 (IL-1, endogenous pyrogen) occurs in the plasma of goats during bacterial-induced febrile episodes (Verheijden et al. 1983). Other studies have demonstrated the existence and activity of neutrophil chemotactic factor, leukocyte migration inhibition factor, and interleukin 2 (IL-2) in goats (Aziz and Klesius 1985, 1986). Caprine macrophages stimulated in vitro with lipopolysaccharide expressed tumor necrosis factor (TNF) and interleukin 6 (IL-6) (Adeyemo

7/Blood, Lymph, and Immune Systems 283 Table 7.5. Reported concentrations of serum proteins from normal goats. Protein

Sex

Unit

Mean ± SD

Total protein

Both Both Both Male Female Both Both Both Male Female Both Both Both Both Both Male Female Both Male Female Both Both Male Female Both Both Both Both Both Male Female Both Both Male Female Both

gm/dl

6.90 ± 0.48

gm/dl

7.53 6.75 ± 0.35 6.90 ± 0.38 3.30 ± 0.33

Albumin

Total globulin Total alpha globulin Alpha1 globulin

Alpha1 globulin

Total beta globulin

Beta1 globulin Beta2 globulin Total gamma globulin

A/G ratio

Fibrinogen (plasma)

3.46 ± 0.41 3.35 ± 0.42 3.60 ± 0.50

Range 6.4–7.0 5.9–7.8

2.7–3.9 2.45–4.35

%

Reference

100

Brooks et al. 1984, Kaneko 1980 Mitruka and Rawnsley 1981 Hsu 1976 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Brooks et al. 1984, Kaneko 1980 Mitruka and Rawnsley 1981 Hsu 1976 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Brooks et al. 1984, Kaneko 1980 Hsu 1976 Kaneko 1980 Brooks et al. 1984 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Hsu 1976 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Brooks et al. 1984, Kaneko 1980 Brooks et al. 1984, Kaneko 1980 Mitruka and Rawnsley 1981 Hsu 1976 Kaneko 1980 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Brooks et al. 1984, Kaneko 1980 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Mitruka and Rawnsley 1981 Brooks et al. 1984, Kaneko 1980

33.5–66.5 44.3

2.7–4.1 10.3

gm/dl gm/dl

0.60 ± 0.06

0.5–0.7 0.5–0.7 0.3–0.6

4.2–8.3

0.3–0.9

5.0–12.5

1.0–2.0

14.8–28.5 14.3

0.45 ± 0.05 0.40 ± 0.04 gm/dl 0.51 ± 0.06 0.68 ± 0.07 gm/dl

gm/dl gm/dl gm/dl

Ratio

1.33 ± 0.14 1.61 ± 0.15 0.90 ± 0.10 0.40 ± 0.02

1.70 1.05 0.86 0.63 0.71 1.05 0.95

± ± ± ± ± ± ±

0.44 0.15 0.14 1.26 1.26 0.11 0.12

gm/dl

et al. 1997). Interleukin 8 (IL-8) and monocyte chemoattractant protein 1 (MCP-1) were expressed by CAE-infected caprine macrophages in vitro (Lechner et al. 1997) and interleukin 16 (IL-16) was expressed at higher levels from peripheral blood mononuclear cells and synovial membrane cells of goats infected with CAE than from cells from control goats (Sharmila et al. 2002). Goats with caseous lymphadenitis produced greater interferon gamma (IFN-γ) responses than uninfected goats when cells in whole blood were stimulated in vitro with either Corynebacterium

0.7–1.2 0.3–0.6 0.5–1.5 0.9–3.0

0.1–0.4

7.0–21.0 30.6

pseudotuberculosis-secreted antigen alone or with pokeweed mitogen (Meyer et al. 2005). Major Histocompatibility Complex (MHC) The MHC of goats is called the goat lymphocyte antigen (GLA) system. Both serologically defined (SD) class I and lymphocyte defined (LD) class II antigens have been identified. Three distinct gene clusters appear to be involved in expression of the GLA: an SD1, an SD2, and an LD, producing five, four, and four antigenic specificities respectively (van Dam et al.

284 Goat Medicine

1979, 1980, 1981). A more recent report suggests as many as twenty-seven class I antigen specificities (Ruff and Lazary 1987). Cross-matching for GLA antigens prolongs skin graft survival time (van Dam et al. 1978a). Also, the degree of humoral immune response has been associated with GLA type. Increased antibody responses to tetanus toxoid were demonstrated in goats with GLA-SD1–2 and SD1–4 specificities (van Dam and van Kooten 1980). Additional information on the caprine MHC is available elsewhere (Obexer-Ruff et al. 1996).

ity in goats, but no signs of hemorrhage were observed (Tomlinson 1983). Hemorrhagic diathesis is considered to be a clinical manifestation of severe, diffuse liver disease in other farm animal species (Radostits et al. 2007). However, a review of liver diseases of sheep and goats did not identify coagulopathy as a clinical outcome of hepatic disease (Fetcher 1983). The only report documenting decreased clotting activity in goats in association with liver disease involved experimental dosing with carbon tetrachloride (Jones and Shah 1982). Anemia

DIAGNOSIS OF HEMIC-LYMPHATIC DISEASES BY PRESENTING SIGN Bleeding Disorders Indications of bleeding disorders include petechial or ecchymotic hemorrhages of mucous membranes, prolonged bleeding from venipuncture sites or surgical wounds, passage of blood from body orifices, or development of subcutaneous or periarticular swellings. Such signs can result from vasculitis, platelet disorders, or coagulopathies. These categories of disease have received limited attention in goats. Inherited afibrinogenemia has been reported in a family of Saanen goats (Breukink et al. 1972). The inheritance pattern is incomplete autosomal dominant. There is complete absence of circulating fibrinogen in homozygous individuals, and goats thus affected do not live past the kid stage. Unchecked umbilical hemorrhage at birth is the most common presentation, but recurrent hemarthroses and subcutaneous and mucosal hemorrhage can also be seen. Clotting time, thrombin time, stage 1 prothrombin, and partial thromboplastin times are all prolonged in afibrinogenemia. Fibrinogen concentration, as measured by bioassay of thrombinclottable protein, is always under 0.15 gm/dl and is usually zero. Acquired coagulation disorders presumably occur in the goat at a rate similar to other species, but the literature on specific causes or cases of coagulopathy in the goat is sparse. Bleeding from the orifices of a dead goat is suggestive of anthrax. Thrombocytopenia is reported as a consistent finding in African trypanosomosis in all affected species, including goats (Davis 1982). The degree of thrombocytopenia and the development of subsequent hemorrhage are directly correlated to the degree of parasitemia that develops. Bracken fern (Pteridium aquilinum) ingestion by cattle can lead to a syndrome of pancytopenia with leukopenia, thrombocytopenia, and anemia. Melena, epistaxis, and widespread petechial and ecchymotic hemorrhage are major clinical findings. While the morbidity rate may be low, the mortality rate is high. There is one report of naturally occurring bracken fern toxic-

Anemia is suggested clinically by pale or white mucous membranes (Figure 7.1), exercise intolerance, tachypnea, tachycardia, possible systolic murmurs, weakness, and (in extreme cases) collapse. When anemia is a result of intravascular hemolysis, then jaundice and hemoglobinuria are also important clinical signs. Signs of anemia are frequently accompanied by signs of hypoproteinemia, particularly intermandibular edema, ascites, and weight loss. Anemia is a common and important clinical presentation in goats. Causes of Hemolytic Anemia Important, established causes of hemolytic anemia in goats include the hemoparasitic diseases anaplasmosis, babesiosis, eperythrozoonosis, and theileriosis; nutritional disorders including copper toxicity, kale ingestion, and consumption of other, regional poisonous plants; and an infectious cause, leptospirosis. Other suspected causes of hemolytic anemia in goats include infections due to Clostridium novyi type D (C. hemolyticum) and Clostridium perfringens type A,

Figure 7.1. White-colored conjunctiva characteristic of a goat with marked anemia. In normal goats, the color is pink to red. (Courtesy of Dr. M.C. Smith.)

7/Blood, Lymph, and Immune Systems 285

as reported in sheep. Experimental poisoning with oak tannins caused marked hemolytic anemia in goats, but naturally occurring oak poisoning is uncommon in this species (Begovic et al. 1978). Experimental infections of sarcocystosis (sarcosporidiosis) produce hemolytic anemia (Dubey et al. 1981), but almost all known naturally occurring infections in goats are subclinical, producing muscle cysts seen at slaughter or necropsy, as discussed further in Chapter 4. Two reports suggest hypophosphatemia as the cause of hemolytic anemia and hemoglobinuria in female goats, but in two of the three reported cases, serum inorganic phosphorus levels were in the normal range (Setty and Narayana 1975; Samad and Ali 1984). In cattle with post-parturient hemoglobinuria, serum inorganic phosphorus levels are well below the normal range. Causes of Blood Loss Anemia Anemia due to loss of blood is of major clinical significance in goats. The condition is most often associated with some form of parasitism. Important causes of blood loss anemia include infestations by Haemonchus spp., and liver flukes, especially Fasciola hepatica. External parasitic causes include sucking lice, ticks, and fleas (Schillhorn van Veen and Mohammed 1975). Predation may be another important cause of blood loss. While wild predators can be expected to kill goats outright unless interrupted, domesticated dogs often maim goats without killing them. Severe hemorrhagic trauma often results.

Causes of Anemia Due to Impaired Erythropoiesis Anemias of this type occur infrequently or are overshadowed by other concurrent and more prominent clinical signs. Nutritional causes include cobalt, copper, and iron deficiencies. Toxic causes include fluorosis and possibly bracken fern ingestion. Anemia of chronic infection also occurs in goats (e.g., in paratuberculosis). Iron deficiency is associated with prolonged feeding of doe’s milk to kids without mineral supplementation or access to forage. Copper deficiency manifests primarily as a neurologic disease in young kids. In experimentally induced cobalt deficiency in goats, a macrocytic, normochromic anemia was observed in addition to weight loss (Mgongo et al. 1981). In naturally occurring cases of cobalt deficiency, ill thrift is a consistent finding, but the presence of anemia is variable (Brain 1983; Black et al. 1988). Nonregenerative anemia has been documented in chronic fluorosis of goats grazing near a superphosphate factory in Egypt (Karram et al. 1984). One incident of bracken fern poisoning has been reported goats. Anemia was present, but may have been due to concurrent parasitism (Tomlinson 1983). Documented causes of anemia in goats are summarized in Table 7.6. The table emphasizes concurrent clinical and laboratory findings, such as hypoproteinemia and hemoglobinuria that can aid in the differential diagnosis of anemia. All of the hemoparasitic diseases, leptospirosis, copper poisoning, phosphorus

Table 7.6. Anemia in goats: Aids for differential diagnosis. Cause of anemia

Pathogenesis and morphologic type

Role of anemia in disease

Total serum protein

Icterus

Hemoglobinuria

Other clinical signs

Comments

Anaplasmosis

Hemoparasitic; extravascular hemolysis; regenerative Hemoparasitic; intravascular hemolysis Hemoparasitic; pathogenesis of anemia unclear Hemoparasitic; mainly extravascular hemolysis Hemoparasitic; mainly extravascular hemolysis

Major

Normal

Likely

No

Often subclinical

Major

Normal

Likely

Likely

Few; abortions can occur, concurrent disease common Fever, diarrhea, abortion

Minor

Normal

Variable

Transient

Major

Normal to low

Unlikely

Unlikely

Major

Normal

Likely

No

Babesiosis

Theileriosis

Trypanosomosis

Eperythrozoonosis

Fever, swollen lymph nodes, lacrimation Fever, edema, lymphadenopathy, weight loss None, but concurrent disease common

Poorly described in goats Primarily a parasite of white cells Seen primarily in Africa

Poorly described in goats

Table 7.6. Continued Cause of anemia

Pathogenesis and morphologic type

Role of anemia in disease

Total serum protein

Icterus

Hemoglobinuria

Other clinical signs

Comments

Leptospirosis

Septicemia; intravascular hemolysis Nutritional; intravascular hemolysis Gastric parasite; blood loss anemia Intestinal parasite; blood loss anemia Liver parasite; blood loss anemia Vascular parasite; blood loss anemia Skin parasites; blood loss anemia

Major

Normal

Yes

Yes

Fever, abortion

Uncommon in goats

Major

Normal

Yes

Yes

Acute death

Major

Low

No

No

Weight loss, edema

Major

Low

No

No

Major

Low

Likely

No

Major

Low

No

No

Diarrhea or dysentery; dehydration Weight loss, edema, ascites, eosinophilia Weight loss, diarrhea, ascites

Goats more resistant than sheep Major cause of anemia in goats Especially young goats affected

Usually minor

Normal to low

No

No

Pruritus, rough hair coat

Trauma/predation

Blood loss anemia

Minor

Normal to low

No

No

Shock, musculoskeletal

Cobalt deficiency

Nutritional; RBC multiplication reduced; macrocytic anemia Nutritional; reduced heme synthesis; microcytic anemia Nutritional; reduced heme synthesis; microcytic anemia Nutritional; hemolytic anemia Anemia of chronic disease, nonregenerative Plant toxicity; Heinz body anemia; regenerative

Minor

Normal to low

No

No

Weight loss, diarrhea, lacrimation, weakness

Minor

Normal

No

No

Enzootic ataxia, or “swayback”

Primarily neurologic; mostly in young goats

Minor

Normal

No

No

None

Uncommon; seen in milkfed kids

Major

Normal

Yes

Yes

None

Some cases reported from India

Minor

High to low

No

No

Weight loss, possible edema

Major

Normal

Likely

No

None

Copper poisoning

Haemonchus spp.

Coccidiosis

Liver flukes

Schistosomosis

External parasites (ticks, fleas, lice)

Copper deficiency

Iron deficiency

Phosphorus deficiency Chronic diseases (e.g., paratubercuosis) Kale poisoning

RBC = red blood cell.

286

Numerous spp. affect the goat Sucking lice and fleas may cause severe anemia Predation a serious problem Mimics gastrointestinal parasitism

Goats more resistant than cattle

7/Blood, Lymph, and Immune Systems 287

deficiency, kale ingestion, and other poisonous plants causing anemia are discussed in detail later in this chapter. Other diseases associated with anemia are discussed elsewhere in the text because other clinical signs predominate. Lymphadenopathy Transient swelling of select regional lymph nodes can be expected in common, localized infections such as mastitis, or subsequent to vaccinations. Persistent lymphadenopathy, however, is a major clinical finding in many important caprine diseases including caseous lymphadenitis, theileriosis, trypanosomosis, melioidosis, tuberculosis, nocardiosis, and lymphosarcoma. Theileriosis and trypanosomosis are discussed in detail in this chapter because of the significant role of anemia in these diseases. The remainder of the diseases are discussed in Chapter 3.

SPECIFIC DISEASES OF THE HEMICLYMPHATIC SYSTEM RICKETTSIAL DISEASES Anaplasmosis Anaplasmosis is an arthropod-borne, rickettsial, hemoparasitic disease of ruminant animals that causes hemolysis. It is usually a subclinical disease in goats and sheep, with goats more likely to manifest clinical signs. Etiology In goats, the causative agent is Anaplasma ovis. In sheep it is A. ovis and a species described in Europe as A. mesaeterum, but not listed in the 1980 Approved Lists (Euzéby 2003); in cattle, A. marginale and A. centrale; and in wild ruminants, A. marginale and A. ovis. Goats may be transiently infected with A. marginale and A. mesaeterum, but do not become clinically ill, and are unlikely to be a reservoir of infection for cattle (Maas and Buening 1981). The discussion here is limited to Anaplasma organisms that produce erythrocytic anaplasmosis. Some rickettsial organisms that infect white blood cells have been transferred to the genus Anaplasma (Dumler et al. 2001) as discussed further in this chapter in the section on tick-borne fever. Epidemiology Caprine anaplasmosis has been reported widely in Africa, India, the Mediterranean countries, and the former USSR. In the United States it occurs in sheep but natural infection of goats has not been reported. Because of the largely subclinical nature of the disease in goats, it is often considered to be of minor economic importance (Akerejola et al. 1979). However, clinical disease due to A. ovis has been reported sporadically

from Nigeria, India, and Iraq (Kuil and Folkers 1966; Mallick et al. 1979; Yousif et al. 1983). More recently, A. ovis infection has been implicated in abortion outbreaks in Boer goats in South Africa, and the economic impact of the disease may be more than previously imagined (Barry and van Niekerk 1987). The disease is spread by a variety of ticks, particularly Rhipicephalus and Dermacentor spp., while Haemaphysalis and Ornithodoros spp. have also been incriminated. Ticks become infected by feeding on infected animals; transmission is probably transstadial and intrastadial, as it is in bovine anaplasmosis. The role of other insects, contaminated syringes, and other veterinary equipment in the mechanical transmission of A. ovis in goats has not been investigated although such transmission is known in bovine anaplasmosis. In utero transmission of A. ovis has been established in sheep, and also confirmed in goats (Barry and van Niekerk 1987a). The severity of clinical disease in cattle increases with advancing age. In experimental infection of goats with A. ovis, no correlation of disease severity with age was discernible although older animals did have a greater reduction in red cell mass (Splitter et al. 1956). A carrier state develops with A. ovis in goats although sterile protective immunity may occur. Recrudescence of clinical disease is possible when the carrier is sufficiently stressed. Pathogenesis The disease produced by A. ovis is primarily an anemia. Parasitized RBCs are destroyed in the spleen and bone marrow and the severity of anemia generally correlates with the percentage of parasitized cells. However, immune-mediated destruction of nonparasitized cells may also contribute to the degree of anemia. In experimentally infected goats, the prepatent period was eight to twenty-three days, with parasitized erythrocytes first evident at an average of fifteen days post inoculation. Maximum parasitemia occurred fifteen to thirty days post inoculation and the lowest RBC counts occurred from twenty-three to thirty-four days after inoculation. On average, RBC count, PCV, and Hb decreased more than 50%. Complement fixing antibody began to appear anywhere from eight days before to one week after the appearance of parasitized erythrocytes and remained detectable in carrier animals for as long as one year (Splitter et al. 1956). Clinical Findings While A. ovis infection is often subclinical in the goat, concurrent disease problems, malnutrition, and other stressors may precipitate clinical anaplasmosis. The most consistent clinical finding may be exercise intolerance, but other signs may be observed including a fever up to 107.5°F (41.9°C), anorexia, depression,

288 Goat Medicine

weakness, pallor of mucous membranes, dyspnea, and increased heart rate. If anemia is extreme, icterus may be present, but hemoglobinuria is an uncommon event. Subclinically infected animals may show only pallor. Diagnosis of anaplasmosis requires laboratory confirmation.

occur simultaneously in the same animal, and laboratory confirmation of anaplasmosis is essential to establish infection. Clinically, the absence of hemoglobinuria distinguishes anaplasmosis from babesiosis, leptospirosis, copper toxicity, and other causes of intravascular hemolysis.

Clinical Pathology and Necropsy

Treatment

Unless there is concurrent disease, the leukogram is likely to be unchanged. Erythrocyte parameters are reduced during clinical and, to a lesser extent, subclinical disease. A mean RBC count of 7.45 × 106/ml, mean PCV of 23.4%, and mean Hb of 6.8 gm/dl have been reported in cases with clinical signs of jaundice, weakness, and ill thrift (Yousif et al. 1983). In terminal cases, RBC counts, PCV, and Hb as low as 2.92 106/ml, 10%, and 2.8 gm/dl, respectively, have been observed (Mallick et al. 1979). Staining of peripheral blood smears with Wright’s or Giemsa stain reveals the organisms in the erythrocytes. Like A. marginale, some 60% to 70% of A. ovis organisms are found on the periphery of the red blood cell, while as many as 40% of A. ovis are submarginal or central in location. The organism is most evident during active parasitemia and may be difficult or impossible to find during the prepatent period or during the carrier state. Even during parasitemia, only a maximum of 6.8% of red cells were observed to be parasitized during experimental subclinical infection, and only 2.7% in naturally occurring clinical disease. Therefore, careful examination of the smear is advisable. Increased MCV, anisocytosis, and polychromasia may be observed during convalescence. To confirm infection during the carrier state, serologic testing may be necessary. Complement fixing antibody titers are highest during and immediately after active parasitemia but persist with variable intensity during the subsequent carrier state. False-negative tests can occur in some carriers. The most definitive test for establishing the carrier state is the inoculation of a splenectomized goat with blood of the suspected carrier. Other serologic tests include a capillary tube agglutination test, a rapid card agglutination test, a fluorescent antibody test, and an enzyme-linked immunoabsorbent assay test. The capillary tube agglutination test has been reported to be reliable in the diagnosis of caprine anaplasmosis (Mallick et al. 1979). Necropsy may reveal thin, watery blood, pallor, and jaundice of tissues. The liver may be enlarged and orange in color.

Treatment is most effective during the parasitemic phase of disease and is directed at reducing the rate of erythrocyte infection. The stress of handling ill animals for repeated therapy may be fatal when anemia is severe. Treatment administered during the prepatent period slows but does not prevent the onset of parasitemia. Oxytetracycline and tetracycline hydrochloride have been used successfully to treat clinically affected goats at an intramuscular dose of 10 mg/ kg bw given once a day for one or two days. However, this dose given once a day for three to five days will not eliminate the carrier state. In cattle, the use of longacting tetracycline preparations at a dose of 20 mg/kg given once a week for two to four weeks has been effective in this regard. Imidocarb diproprionate may be useful in caprine anaplasmosis but information on dosage and treatment schedules for goats is limited.

Diagnosis Anaplasmosis occurs in regions where other caprine hemoparasitic diseases also occur, including babesiosis, eperythrozoonosis, cowdriosis, and theileriosis. In fact, it is not unusual for some of these conditions to

Control In general, efforts to control the spread of anaplasmosis by controlling the biologic vectors are not practical except on a local basis through repeated dipping or spraying. There is no evidence that available A. marginale bovine vaccines offer any protection against A. ovis infection in small ruminants, and no specific vaccine for A. ovis is currently available. In lieu of vaccination, prophylactic antibiotic administration might be used to prevent the spread of infection in the case of an outbreak. In exposed cattle, oxytetracycline is administered at a dose of 1 to 2 mg/kg bw daily for ten days to prevent infection. The cost benefit of this program is difficult to evaluate in goats because uncomplicated caprine anaplasmosis is most often a subclinical disease. Eperythrozoonosis This hemoparasitic disease of goats is of little clinical and economic significance and is caused by the organism Eperythrozoon ovis. This organism, formerly classified in the Rickettsiales, is now known to belong to the Mycoplasmatales (Neimark et al. 2004), but the differences with classical Mycoplasma spp. do not warrant fusion of the two genera (Uilenberg et al. 2006). Epidemiology While E. ovis infection of sheep is known to occur widely in Europe, Africa, Australia, North America, and the Middle East, reports of infection in goats have

7/Blood, Lymph, and Immune Systems 289

come only from Pakistan, South Africa, Australia, and most recently, Cuba (Joa et al. 1987). Transmission is probably by biting insects, contaminated needles, and surgical instruments. In Tasmania, a serologic survey indicated widespread infection in sheep with E. ovis, but virtually no infection in goats, suggesting the possibility of different vectors for the two animal species, or a difference in host susceptibility to chronic infection (Mason et al. 1989). Etiology and Pathogenesis The same organism, E. ovis, is infective for both sheep and goats, though a dimorphism has been noted. On Giemsa-stained smears, the organism on sheep erythrocytes demonstrates a large ring form, while in goats smaller ring and coccoid forms predominate (Daddow 1979, 1979a). In both small ruminant species, subclinical or latent infection is the rule; when clinical disease appears, it is often triggered by concurrent problems such as malnutrition or gastrointestinal parasitism. In experimental infection the prepatent period is six days for both species but the degree and length of parasitemia is shorter in the goat, lasting four weeks compared with six in the sheep. A carrier state developed in goats, with blood infective as long as fourteen months after infection (Daddow 1979). Clinical Signs Clinical disease is rarely observed in goats. The disease is characterized in sheep by weakness, unthriftiness, anemia, and mild icterus. Staggering and stiffness of the hindquarters have also been reported in sheep. Diagnosis The organism can be found on erythrocytes in Giemsa-stained blood smears during the parasitemia. However, clinical signs of anemia may not be recognizable until the waning stages of parasitemia. Antibody may also be detected with the CF test for up to three weeks after clinical signs are observed. However, falsenegative results may occur (Daddow 1977). Low levels of antibody may also be intermittently detectable during subsequent carrier states. It is recommended that the CF test be used on a herd basis rather than for individual diagnosis. Differential diagnoses include other hemoparasites, especially anaplasmosis, malnutrition, gastrointestinal parasitism, and cobalt deficiency. Treatment and Control Treatment may alleviate clinical disease, but may not clear the carrier state. Single-dose therapy with either neoarsphenamine at a dose of 30 mg/kg, antimosan at 6 mg/kg, or oxytetracycline at 6.6 mg/kg have been recommended for sheep. No specific thera-

peutic evaluations have been reported in goats. Control involves good preventive medicine programs to avoid predisposing conditions as well as the single animal use of needles and surgical equipment. Tick-borne Fever Tick-borne fever is a tick-transmitted rickettsial disease of goats, sheep, and cattle caused by the organism Anaplasma phagocytophilum, formerly classified in the genus Ehrlichia (E. phagocytophila). There are several strains of this organism which differ in host pathogenicity—the zoonotic HGE agent that causes human granulocytic ehrlichiosis (or human anaplasmosis), strains formerly called E. equi that cause equine ehrlichiosis (or equine anaplasmosis), and others more adapted to cattle and/or small ruminants that cause pasture fever or tick-borne fever. Dogs can also be infected. The condition is characterized in all ruminant species by fever and leukopenia. Abortions commonly occur in affected sheep and cattle, but not goats. Tickborne fever in endemic areas causes noticeable losses in goats because of decreased milk production and secondary infections resulting from impaired immune responses. Epidemiology The disease occurs in cattle and sheep throughout Europe, wherever its tick vector, Ixodes ricinus, occurs. I. persulcatus in eastern Europe is also a vector. A similar organism has also been reported from India. Strains causing human and equine ehrlichiosis (or anaplasmosis) in the United States are transmitted by I. scapularis. Reports of naturally occurring tick-borne fever in goats have come only from Scotland and Norway (Melby and Grønstøl 1984; Gray et al. 1988). It is reasonable to assume, however, that where the disease occurs in sheep, goats are susceptible. In Europe, the tick vector Ixodes ricinus favors wet, cool, woodland pastures, and forest. In Scotland, the infection has been identified in feral goats, which are considered a wildlife reservoir along with the red, roe, and fallow deer (Foster and Greig 1969). The incidence of disease increases in spring and autumn, with increased tick activity. Etiology and Pathogenesis The causative agent of tick-borne fever in cattle and small ruminants is Anaplasma (Ehrlichia) phagocytophilum, but bovine and ovine strains are recognized. Strains isolated from sheep readily produce the disease experimentally in goats and vice versa. The infectivity of the bovine strains can be less in small ruminants than cattle. Cross immunity between strains is not always complete. Related organisms, with other tick vectors, are Anaplasma or Ehrlichia bovis in cattle and Ehrlichia ovina in sheep.

290 Goat Medicine

Infected ticks introduce the organism into host animals in their saliva during blood feeding. Because the organism is passed transstadially and not transovarially in the tick, only nymphal and adult stage ticks can transmit the infection to ruminants. When entering the host’s bloodstream, the organism invades neutrophilic granulocytes, and to a lesser extent macrophages, where it replicates. In experimental infection of goats, high fever and granulocyte inclusions are seen by day three after infection. By day seven after infection, the total WBC count may drop to 27% of the level before infection. There is a transient lymphopenia and a persistent neutropenia, with no left shift. A transient eosinophilia is also observed around day five after infection (Van Miert et al. 1984). It is believed that the invasion of leukocytes stimulates interleukin-1 (endogenous pyrogen) release that accounts for the high fever, rumen stasis, and other signs seen in clinical disease. The transient lymphopenia and neutropenia may impair immune defenses and predispose affected animals to serious secondary infections and increased risk of mortality. There is limited information on morbidity and mortality rates in goats. In a report from Scotland, twentyfive goats were at risk. Thirteen had detectable antibody responses to tick-borne fever, seven showed clinical signs of disease, and one died (Gray et al. 1988). In a Norwegian report, fifty of 103 goats in a dairy herd were affected by tick-borne fever, including all goats younger than one year of age (Melby and Grønstøl 1984). While a low level of immunity develops after infection, the organism has been reported to persist in the blood stream of infected sheep for as long as two years. Clinical Signs Clinical signs reported in goats include a fever often higher than 106°F (41°C) that persists for three to six days accompanied by dullness, anorexia, decreased rumen motility, tachycardia, tachypnea, occasional shivering, and coughing. In lactating does, there is a significant drop in milk production. Animals should be examined for ticks. In contrast to sheep and cattle, abortion and secondary bacterial infections have not played a significant part in reported outbreaks of caprine tick-borne fever. Complete recovery may take several weeks. Clinical Pathology and Necropsy By day three of infection, the organism should be readily apparent in neutrophils in peripheral blood smears stained with methylene blue. The organism is located within vacuoles in the cell cytoplasm. Leukopenia is marked, with white blood cell counts commonly less than 3,500 by day seven. Initially there is a reversal of the neutrophil-to-lymphocyte ratio because

of a transient lymphopenia. Subsequently, lymphocyte numbers return toward normal and neutrophil numbers continue to decrease. A decrease in serum alkaline phosphatase has been observed in the acute phase of tick-borne fever in goats, but the cause is unclear. There are no remarkable necropsy findings. Diagnosis A presentation of high fever in tick-infested goats should suggest tick-borne fever in endemic areas. In the acute phase of disease, identification of the organism in neutrophils in peripheral blood smears is diagnostic. Serologic evidence of infection may be obtained by complement fixation test or counter immunoelectrophoresis (Webster and Mitchell 1988), as well as an indirect immunofluorescent test (Jongejan et al. 1989). Louping-ill, a viral disease, is also transmitted by Ixodes ricinus and can produce fever. The two diseases can occur concurrently in endemic areas. Louping-ill produces neurologic signs, and serologic evidence of infection can be obtained. Treatment and Control Several drugs have been evaluated for treatment of goats (Anika et al. 1986, 1986a). A single intravenous injection of oxytetracycline at a dose of 10 mg/kg resulted in a return to normal body temperature in six hours and killing of intracellular organisms. A single intravenous dose of trimethoprim (20 mg/kg) in combination with sulphamethylphenazole (50 mg/kg) and sulphadimidine (50 mg/kg) was also effective, as is chloramphenicol in a single intravenous dose of 50 mg/kg, where its use is permitted. Spiramycin and ampicillin were not effective against tick-borne fever. Control of tick-borne fever involves controlling exposure of goats to ticks. Pasturing young goats in tick-infested areas during seasons of low tick activity may promote immunity and reduce the severity of disease that develops during periods of increased exposure. The use of acaricides during seasons of high tick activity may also be beneficial.

BACTERIAL DISEASES Leptospirosis Leptospirosis is a contagious, zoonotic disease caused by various serovars of the spirochete Leptospira interrogans. Goats and sheep are less susceptible to leptospirosis than cattle, swine, dogs, and man, and the disease is uncommon in small ruminants. Most leptospiral infections of goats are probably subclinical, although epizootics of abortion have been reported, as have outbreaks of acute septicemia with hemolytic jaundice. The two syndromes can occur simultaneously. Numerous serologic prevalence surveys of

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caprine leptospirosis have been done, but descriptions of clinical disease are limited. Etiology Several serovars of L. interrogans have been identified in clinical caprine leptospirosis, most notably L. pomona, L. grippotyphosa, L. icterohemorrhagiae, and L. serjoe. Additional serovars identified infrequently in apparently healthy goats on serologic survey include L. autumnalis, L. australis, L. balcanica, L. ballum, L. bataviae, L. bratislava, L. canicola, L. hardjo, L. hyos, L. panama, L. pyrogenes, and L. wolfii. Epidemiology Leptospiral infection of goats has been reported from Brazil, Israel, Iran, India, Kenya, Nigeria, Turkey, Spain, Italy, Portugal, the former USSR, Jamaica, Grenada, New Zealand, and the United States. Serious outbreaks of disease with high morbidity and mortality rates in goats have been reported from Iran and Israel. In both countries, L. grippotyphosa was involved. In the Iranian epizootic, morbidity was between 90% and 100% for both sheep and goats, but goats showed a mortality rate of 42%, compared with 18% in sheep (Amjadi and Ahourai 1975). In Israel, the morbidity rate was also higher in affected goats than sheep, and goat mortality was also as high as 44% in some herds (Van der Hoeden 1953). In Nigeria, abortions in a university herd of west African dwarf goats were diagnosed as due to leptospirosis. Affected animals also showed diarrhea and jaundice. The predominant serovar was L. pomona, but antibodies to L. grippotyphosa and L. icterohemorrhagiae were also identified in some individuals (Agunloye et al. 1996). In southern Spain, the seroprevalence was reported as 16.1% in goats and leptospirosis, primarily L. pomona, accounted for 2.6% of 262 caprine abortion outbreaks investigated over a fifteen-year period (Leon-Vizcaino et al. 1987). In a Jamaican survey, 35% of 1,545 goats tested were seropositive (Oliveira 1987). In one Brazilian study, the seroprevalence was 0.9% in confined or semiconfined dairy herds, but 6.7% among goats kept under subsistence conditions (Silva et al. 1984). In a more recent study from Brazil, seroprevalence was higher in goats that grazed more than two hours per day as compared to those that grazed less, suggesting a greater risk of exposure to leptospires through grazing. Seroprevalence was also greater in goats in tropical climatic settings than in temperate settings, suggesting that heat stress and rainfall contributed to infection (Lilenbaum et al. 2008). The predominant serovar in the survey was L. hardjo The goat is most likely exposed to infection from wild rodents or other infected livestock shedding the organism in urine, and is not itself considered a persistent reservoir of infection (Schollum and Blackmore

1981). However, goats can shed the organism in urine for at least one month after an acute infection and should be considered as potential sources of new infections during that time. Leptospires most commonly gain entrance to the host through skin or mucosal abrasions. They are readily killed by drying, but thrive under warm, moist conditions and will persist in contaminated, standing water for long periods. In the Iranian epizootic, the outbreak was attributed to a period of frequent rain, flooding, and warm weather that favored the environmental survival and spread of leptospires. In the Israeli report, the incidence of clinical cases fell off rapidly when the wet winter season ended and dry spring weather began. In Brazil, as well, the occurrence of leptospirosis in goats is associated with increased rainfall (Alves et al. 1996) Pathogenesis Infection leads to a septicemic leptospiremia, followed by clearance of the blood as antibody response develops, and subsequent localization of the organism in the kidney with leptospiruria. Death may occur during the septicemic phase. Hemolytic anemia may develop as a result of hemolysin production by certain serovars of L. interrogans. In sheep, at least, leptospirosis can also produce immune mediated hemolytic anemia. Abortion results from transplacental passage of leptospires during the septicemic phase with death of the fetus. This is more likely to occur in the second half of pregnancy. In animals that survive acute infection, a strong immunity develops against the inciting serovar, but cross immunity does not occur. Clinical Signs In acute leptospirosis goats may show a fever of 104°F to 106.7°F (40°F to 41.5°C), marked depression, and inappetence after an incubation period of four to eight days. Heart rate is elevated and the animals are dyspneic. Icterus of mucous membranes is a prominent finding, and petechial hemorrhages of the conjunctivae may be observed. Reddish brown urine indicative of hemoglobinuria is evident. Pregnant animals often abort. In untreated animals, death can occur within two to three days. Subclinical infections commonly occur in seemingly unaffected herd mates. Clinical Pathology and Necropsy A moderate to severe hemolytic anemia develops concurrently with the onset of clinical signs, and hemoglobinuria is present. In animals that do not die, there is soon evidence of a regenerative erythroid response. Leukopenia occurs during the acute phase of disease in cattle, but has not been reported in goats. Thrombocytopenia can occur in all affected species,

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with or without evidence of concurrent disseminated intravascular coagulation. At necropsy, icterus is pronounced and extensive in acute leptospirosis (Amjadi and Ahourai 1975). Edema and ecchymosis of the subcutis and serous membranes occur. Lungs may be pale and edematous with widening of the interlobular septa with yellow serous fluid. The liver may be enlarged and friable with extensive subcapsular hemorrhage. The kidneys are swollen, dark brown, and have a rough surface. Grayish streaks may be noted in the renal cortex. Histologic examination indicates renal tubular degeneration and a marked interstitial nephritis. Silver stains reveal spirochetal organisms in the renal tubules. Diagnosis Definitive diagnosis depends on isolation of the organism and identification of the serovar. During the leptospiremic phase, the organism may be isolated from blood, but only with difficulty. The potential for isolation from the urine during the leptospiruric phase is somewhat better. It is advised to initiate cultures from fresh specimens right at the farm by inoculating a suitable transport medium, or by injecting urine into guinea pigs or hamsters. In abortion cases, fetal kidney, lung, and pleural fluid should be examined microscopically for leptospires using silver stains or immunofluorescence techniques. The most practical diagnostic approach is the identification of rising antibody titers in acute and convalescent serum samples taken seven to ten days apart in clinically affected animals. The microscopic agglutination test (MAT) is most commonly used. The MAT measures both IgM and IgG antibody and is more useful in the diagnosis of acute disease than chronic disease. The range of positive titers observed in goats during outbreaks of abortion was 1 : 200 to 1 : 12,800 using the MAT (Leon-Vizcaino et al. 1987). In Israel, titers of 1 : 100 were commonly encountered in animals with no history of clinical leptospirosis. Therefore, titers of 1 : 300 or more were considered as evidence of active infection. A titer of 1 : 30,000 was reported as early as day four of illness in a goat (Van der Hoeden 1953). Other serologic tests, including indirect ELISA and antibody-capture ELISA, are also now being used in cattle, but reports of their use in goats are limited. Where both diseases occur, babesiosis must be ruled out because of the similar presentation of hemolytic anemia, fever, and possible abortion. Identification of characteristic piroplasms in RBCs would confirm babesiosis. Anaplasmosis may also produce fever, anemia, and abortion, but icterus and hemoglobinuria are uncommon. Other differential diagnoses for hemolytic anemia with hemoglobinuria include copper toxicity and plant intoxications, especially kale poisoning.

Treatment Goats with acute leptospirosis have been reported to respond to a combination of streptomycin and penicillin (Amjadi and Ahourai 1975). In other species, streptomycin used at an intramuscular dose of 12 mg/ kg twice a day for three days controls the septicemia. A single intramuscular injection of 25 mg/kg of streptomycin may clear leptospires from the kidney in the subsequent leptospiruric phase. A single intramuscular injection of long acting oxytetracycline at a dose of 20 mg/kg bw may be effective where the use of streptomycin in food animals is prohibited. Tetracyclines administered in the feed at a dose of 3 mg/kg for one week before and two weeks after exposure to leptospirosis has prevented clinical signs in calves, though infection did occur. Supportive therapy must be considered in acute leptospirosis because anemia can be severe and the potential for renal failure is high due to primary interstitial nephritis and secondary hemoglobinuria with cast formation. Continuous intravenous fluid therapy is indicated to maintain renal output, and blood transfusions may be considered when the degree of anemia appears life-threatening. Control Early recognition and initiation of streptomycin or tetracycline therapy may reduce the number of clinical cases. Concurrent use of vaccination with the appropriate serotype vaccine in the face of an outbreak has been shown to reduce the incidence of new cases and abortions in cattle. Active and recovered cases should be isolated because of the possibility of organisms continuing to be shed in the urine. Always remember that leptospirosis is a potential zoonosis. Prevention is based on environmental hygiene measures such as rodent control, elimination of standing water, and avoidance of damp bedding; screening or prophylactic treatment of newly acquired animals for elimination of the carrier state; and vaccination. Little or no protective cross immunity occurs among the various serovars of L. interrogans, so vaccination should be based on serologic evaluation of prevailing serovars. Multivalent vaccines suitable for use in goats are available. All animals older than three months of age should be vaccinated. Kids of vaccinated dams nursing colostrum should be protected by passive antibody up to three months of age. Annual or semi-annual revaccination is practiced in cattle. While the duration of protective immunity in goats has not been reported, semi-annual revaccination of goats has been suggested. When considering vaccination, bear in mind that leptospirosis in goats is uncommon, and the cost-tobenefit ratio of routine vaccination for leptospirosis in

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goats is not known. In an American study undertaken to evaluate health status of goats in relation to management practices in forty-three herds, no cases of leptospirosis were reported in any of the herds, regardless of whether they were vaccinated (Hagstad et al. 1984). The prevalence of leptospirosis in the practice area should be assessed in consideration of vaccination programs. Farmers, herders, veterinarians, milkers, and slaughterhouse workers have an increased occupational risk of exposure to this zoonotic disease and should exercise appropriate hygienic precautions to prevent infection. Anthrax Anthrax is a well known, infectious disease of livestock with zoonotic potential. The disease in goats is very similar to that in other ruminant species. This septicemic condition is characterized by a failure of the blood to clot. This is commonly noted at death by a bloody discharge from the nose and mouth. Etiology and epidemiology Bacillus anthracis is the cause of anthrax in herbivores and humans. The organism is characterized by the ability to produce spores, on exposure to air, that are capable of persisting for longer than fifty years. Anthrax is endemic in many tropical and subtropical regions of the world. The major route of transmission in animals is ingestion of spores residing in soil during periods of grazing. The disease has a seasonal occurrence, and is predisposed by environmental temperatures exceeding 59°F (15°C), periods of drought, or heavy rains. Goats are susceptible to anthrax, but reports of the condition in goats are uncommon, perhaps because they are not ground grazing animals by nature. Outbreaks in goats have been reported from Nigeria (Okoh 1981), Texas (Whitford 1982), China (ProMED-mail 2006), and Ethiopia (Shiferaw, 2004), and are possible wherever anthrax is endemic in other species. Grazing is not an absolute prerequisite for exposure to anthrax. Zero-grazed goats in Texas that were fed hay and a pelleted feed were confirmed with anthrax (ProMED-mail 2008). It is presumed that one or more of the provided feeds was contaminated with anthrax spores. Additional information on the epidemiology of anthrax is available elsewhere (Radostits et al. 2007). Clinical Findings and Diagnosis The disease is characterized most commonly by a peracute, fatal course, with most affected animals found dead, the result of bacteremia and toxemia. In acute cases, goats may be noted to be salivating and extremely depressed with the head hanging down. Over a period of one to two days they become recumbent and moribund, and die. Observation of bleeding

from the nostrils and mouth of dead animals is characteristic of anthrax. Carcasses of suspect animals should not be opened at the site of death because this will release spores that will contaminate the environment. If movement of the carcass is not possible, then carefully aspirated blood samples and superficial lymph node aspirates can be taken and submitted for bacterial culture. If necropsy is performed, the blood is unclotted and the spleen is dramatically enlarged. Hemorrhages on serosal surfaces suggestive of septicemia are observed. The organism can be cultured from tissue. The differential diagnosis must include all potential causes of sudden death as discussed in Chapter 16. Treatment and Control Antiserum and/or antibiotics including tetracyclines, streptomycin, and penicillin may be effective therapies in early cases in the face of an outbreak. In endemic areas, effective vaccines are usually given annually and can be used safely and effectively in goats. Anthrax is an important zoonotic disease. Transmission is usually by direct handling of hair, wool, skins, or carcasses of infected or contaminated animals. The disease can also be spread by inhalation of spores. A textile mill worker in North Carolina was diagnosed with anthrax that was traced to handling cashmere goat hair imported from endemic regions of western Asia (Briggs et al. 1988). Cases of cutaneous and inhalation anthrax in humans have been reported in the United States in association with the handling of goat skins imported from Africa for drum making (Kaplan 2007). There are numerous reports from developing countries of human cases of anthrax occurring among villagers who eat meat from livestock that have died of anthrax, including goat meat (Boutin et al. 1985; ProMED-mail 2006). Gloves and masks should be worn when handling carcasses or animal products suspected of being contaminated with anthrax. Animals dying of unknown causes or of suspected anthrax should not be eaten. Carcasses should be burned or buried deeply to avoid dissemination and persistence of spores in the environment.

PROTOZOAL DISEASES Babesiosis Babesiosis is a tick-borne protozoan hemoparasitic disease of goats. In those regions where it occurs, the economic losses associated with caprine babesiosis may be significant, particularly around the Mediterranean and in the Middle East and India. Etiology Two main species of Babesia infect sheep, B. motasi and B. ovis, but in goats B. motasi infection

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predominates. B. motasi is classified as a large Babesia sp. with a length of 2.5 to 4 microns while B. ovis is a small Babesia sp. with a length of 1 to 2.5 microns. Another large species, B. crassa, has been found in Iran and a few other countries, including Turkey. It is reported to be infective, but probably nonpathogenic, for goats. Another small species, B. taylori, infective for goats has been reported from India but the current status of this species is unclear. The agents causing bovine babesiosis are not pathogenic for goats although inapparent infections of goats with B. bigemina have been observed. Ticks serve as biological vectors but mechanical transmission is also possible.

degree of parasitemia, and immune-mediated hemolysis may also be occurring. In other species, infection may lead to the development of neurologic signs from cerebral thrombosis, hypotension from activation of plasma kallikrein, and disseminated intravascular coagulation. These syndromes have not yet been reported in the goat. Antibodies are produced in response to infection. A protective immunity develops in nonfatal infections. It does not completely prevent reinfection, but does inhibit recurrence of clinical disease with the same-infecting strain. The development of a carrier state in goats is not addressed in the literature.

Epidemiology

Clinical Signs

B. motasi infection of small ruminants has been reported from much of Europe, the Middle East, the former USSR, India, southeast Asia, and parts of Africa (Purnell 1981). The primary biological vector for B. motasi is the tick Haemaphysalis punctata, although it is also likely to be transmitted by other species in the genus Haemaphysalis. Reports of transmission by Dermacentor silvarum and Rhipicephalus bursa are probably erroneous (Uilenberg et al. 1980). Transovarial and transstadial tick transmission occurs. Several strains of B. motasi exist, with variable infectivity and pathogenicity for goats (Purnell 1981a). An outbreak of naturally occurring disease in both sheep and goats caused by B. motasi has been reported from India (Jagannath et al. 1974). A strain of B. motasi isolated from sheep in Wales produced fever and anemia in a splenectomized goat, but pathogenicity for intact goats was not evaluated (Lewis et al. 1981). Babesiosis was the cause of debilitating disease in sheep and goats in southwest Nigeria but caused death only in goats (Adeoye 1985). B. ovis is transmitted primarily by Rhipicephalus bursa. The geographic distribution of B. ovis coincides in part with that of B. motasi, but is associated primarily with disease in sheep where it occurs. Natural infection of goats with B. ovis has been reported only from Somalia, and the infection was subclinical (Edelsten 1975). The pathogenicity of Babesia spp. in goats and sheep may be intensified by concurrent infections, particularly other hemoparasites. No cross immunity develops after infection with either B. motasi or B. ovis.

Affected goats may have fevers as high as 107°F (41.7°C) and show anorexia, weakness, and signs of anemia, including dyspnea and tachycardia. Sheep consistently show icterus and hemoglobinuria, with coffee-colored urine. These signs occur less consistently in goats, but aid in diagnosis when present (Jagannath et al. 1974). Additional signs of coughing and diarrhea have been reported but may be because of other concurrent infections. Affected goats may harbor ticks, though infective ticks may have dropped off before clinical signs develop. Morbidity and mortality rates can be high. Death can occur within forty-eight hours of the onset of signs. Chronic infections may occur, with anemia and ill thrift the prominent findings.

Pathogenesis Merozoites introduced by feeding ticks invade erythrocytes. Asexual reproduction of the protozoa occurs within the red blood cells to form a pair of trophozoites that are released and re-invade other red blood cells. The release of trophozoites from parasitized red cells results in intravascular hemolysis. The degree of anemia does not always correlate with the

Clinical Pathology and Necropsy Giemsa-stained blood smears should be examined for evidence of piroplasms. Thin smears are usually adequate at the height of parasitemia, but in chronic cases or when parasitemia is low, thick blood smears prepared from ear vein blood are preferred. Blood from several animals in a suspect group should be examined to avoid missing the diagnosis. B. motasi is a large piroplasm and occurs in single and double pear-shaped forms. B. ovis is a smaller piroplasm and often assumes a round form near the periphery of the erythrocyte. The Babesia piroplasms must be distinguished from Theileria piroplasms that can also affect goats and have a similar geographic distribution. An indirect fluorescent antibody test can be used for the serodiagnosis of B. motasi infection, with titers of 1 : 640 or more considered as evidence of infection (Lewis et al. 1981). At time of necropsy, the predominant findings are splenomegaly, lymphadenopathy, and enlarged liver. Icterus and hemoglobinuria are variable. Peripheral blood should be examined for piroplasms. Diagnosis The diagnosis of caprine babesiosis is suggested by signs of anemia, hemoglobinuria, and acute collapse in

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animals where babesiosis is known to occur. Definitive diagnosis depends on the identification of the organism in blood smears. Theileriosis can be differentiated by the morphology of piroplasms and a more prominent lymph node enlargement. Anaplasmosis does not normally produce hemoglobinuria. When hemoglobinuria is present, plant poisonings, copper toxicity, anthrax, and leptospirosis must also be considered. Treatment A single dose of prescribed treatments is often satisfactory. The diamidine derivatives diminazene and imidocarb diproprionate are effective at doses of 3 mg/kg and 1 to 2 mg/kg, respectively. Diminazene in intramuscular doses as high as 12 mg/kg have been used in goats without adverse effect (Bannerjee et al. 1987). Most of the earlier drugs used for treatment, such as the quinuronium sulfate compounds, are no longer commercially available. Control No specific recommendations for control of caprine babesiosis have been made. In cattle and sheep, control efforts are directed at vaccination and reduction of tick infestations using acaricides. Vaccination protocols include vaccination with live protozoa in conjunction with imidocarb chemoprophylaxis, or chemoprophylaxis alone, leading to a controlled natural exposure and self-immunization. Inoculation with indigenous strains of Babesia in conjunction with chemoprophylaxis (infection and treatment) may be essential for survival of exotic breeds of goats imported into areas where babesiosis is enzootic. Theileriosis Theileriosis is a tick-borne protozoal disease of ruminants affecting primarily the hemic-lymphatic system. Etiology and Epidemiology Theileriosis has received little direct attention in goats and much has been inferred from the disease in sheep. As a result, discrepancies occur in the literature concerning pathogenicity for goats. Pathogenic Theileria spp. infecting goats and sheep include T. lestoquardi (earlier known as T. hirci) and two species described recently in China. There is some confusion about the nomenclature of these Chinese species; they have been designated as Theileria sp. (China 1) and Theileria sp. (China 2) (Ahmed et al. 2006). They have also been named T. luwenshuni and T. uilenbergi (Yin et al. 2004), but it may not be quite clear to which of the two species each of these names refers. There are also several nonpathogenic species in small ruminants causing benign theileriosis, which may confuse the picture. T. ovis is distributed widely

throughout Europe, Asia, and Africa. In Africa, it may be confused with another species, T. separata, and in Europe with one or two other species, as yet unnamed. T. lestoquardi is most often associated with high morbidity and mortality rates and infection with T. lestoquardi is known as malignant small ruminant theileriosis. It has produced serious losses in sheep and goats in northern Africa, including the Sudan, Asia, the Middle East, southern Europe, and the southern former USSR. In a report from Iraq, however, a strain of T. lestoquardi, responsible for 100% morbidity and 89.7% mortality rates in a flock of sheep, produced no clinical disease when inoculated in a goat (Hooshmand-Rad and Hawa 1973). Similarly, in an Indian study, the infection was transmitted to sheep but not goats (Sisodia and Gautam 1983), and in the Sudan infection of goats with T. lestoquardi appears to be rare. Species of Theileria highly pathogenic for cattle do not cause disease in small ruminants. Infections in goats with nonpathogenic small ruminant species of Theileria are also much less common than in sheep, and goats may be refractory to some species infective for sheep. T. lestoquardi is transmitted by Hyalomma anatolicum in Asia, while the recently described species in China are transmitted by Haemaphysalis quinghaiensis. The tick vectors of T. ovis in sub-Saharan Africa are unknown. Transmission of T. ovis reported in South Africa by Rhipicephalus evertsi in fact involved T. separata. Rhipicephalus bursa is reported as a vector in the former USSR, north Africa, and Asia. Haemaphysalis punctata is the vector in Great Britain of a nonpathogenic species. Pathogenesis Sporozoites enter the host by the bite of infected ticks. The parasites are initially located in the spleen and lymph nodes, where they invade lymphocytes and produce schizonts. These schizonts, which early in the infection contain large nuclei, and later small ones, are readily identifiable in Giemsa-stained smears of lymph node aspirates or biopsies, and are referred to as Koch’s Blue Bodies. After lysis of lymphocytes, micromerozoites enter the blood stream as piroplasms and invade erythrocytes. The piroplasm is polymorphic in red blood cells, exhibiting ring, oval, commashaped, or rod forms. Additional replication occurs in the red blood cells, and the sexual stages of the life cycle occur in the tick. The anemia of theileriosis is less severe than that seen in babesiosis, the other piroplasm of goats. Clinical Signs In malignant theileriosis (T. lestoquardi infection), clinical signs initially include fever, increased heart

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and respiratory rates, anorexia, dullness, and depression. Lymph nodes are markedly swollen. Serous nasal discharge and lacrimation develop, and the conjunctivae are congested. The clinical course may last from two to three weeks; during that time, the animal may experience a decrease in milk production, coughing, rough hair coat, emaciation, weakness, recumbency, and death. A mild to moderate anemia may be observed and, in sheep, icterus has been inconsistently reported. In benign theileriosis, transient fever and mild lymph node swelling may occur and be overlooked under field conditions. Clinical Pathology and Necropsy Anemia and lymphopenia may be noted in the hemogram. Koch’s Blue Bodies may be identified in Giemsa-stained smears of lymph nodes or characteristic piroplasms seen in circulating red blood cells. On examination after death, lymph nodes, spleen, and liver are all enlarged. The liver is yellow and the kidneys may show patchy hemorrhagic infarcts. Necrotizing ulcers ringed by hemorrhage may be seen in the abomasum and intestine. Diagnosis Diagnosis is based on identification of Koch’s Blue Bodies in lymph nodes or piroplasms in erythrocytes. The piroplasms must be distinguished from those of Babesia spp. Molecular methods, comparing selected sequences of nucleotides in DNA, have become important research tools for species identification and phylogenetic studies. Treatment and Control Specific information on the treatment of caprine theileriosis is lacking. In cattle, high doses of longacting oxytetracycline, 20 mg/kg of the 200 mg/ml formulation given intramuscularly, have been therapeutically effective against T. parva and T. annulata, only when administered very early in the incubation period. A napthoquinone, parvaquone, at 10 mg/kg intramuscularly, given twice to cattle is curative as late as four days into the clinical disease, and a related drug, buparvaquone, is even more effective. An anticoccidial compound, halofuginone, with a single oral dose of 1.2 mg/kg has also been effective against bovine theileriosis. However, even slight overdosing may produce severe adverse effects, so extrapolation to goats is inadvisable without additional evaluation. Control of caprine theileriosis involves control of the tick vectors primarily through dipping programs. Vaccine development is progressing for control of bovine theileriosis, including the use of attenuated schizonts of T. annulata in cell culture, but little activity has been reported with small ruminant species of Theileria. However, because schizonts of T. lestoquardi can

be grown in cell culture, attenuation should be attempted. Trypanosomosis Trypanosomosis is a major constraint on ruminant livestock production in Africa, including goat production. The impact of South American trypanosomosis on goats is largely unexplored and is only briefly discussed. Salient characteristics of the important animal and human trypanosomes and their pathogenicity for goats are summarized in Table 7.7. Though often referred to as trypanosomosis, the preferred name for disease caused by trypanosome infections is trypanosomosis (Kassai et al. 1988). Etiology The trypanosomes are flagellate protozoa characterized by a kinetoplast and an undulating membrane. Most trypanosomes require two hosts to complete their life cycle, a hematogenous insect vector and a vertebrate host. In sub-Saharan Africa, cyclic transmission of the parasite to mammalian hosts occurs via numerous species of tsetse flies (Glossina spp.) during feeding by the flies. Elsewhere in the world, mechanical transmission by other species of biting flies is the primary mode of infection. A recent, detailed and informative review of African animal trypanosomes and the diseases they cause is available elsewhere (Connor and van den Bossche 2004). T. congolense is the most common trypanosome of goats in Africa. T. vivax is the second most common. Natural infection of goats with T. brucei is also sporadically reported. Goats are susceptible to T. uniforme, a trypanosome of the vivax group in Uganda and Zaire, but only mild infections occur. T. simiae, a trypanosome of swine and camels, is transmissible to goats by either Glossina spp. or biting flies but causes mostly mild or subclinical disease. Goats and other domestic animals are relatively resistant to T. gambiense, the cause of West African human sleeping sickness. When infection does occur, the clinical course is chronic. T. rhodesiense, the cause of East African sleeping sickness in humans, is an uncommon cause of caprine disease. A nonpathogenic trypanosome, T. theodori, is found incidentally in goats in Israel. It is transmitted by a hippoboscid fly, Lipoptena caprina. This organism is morphologically similar to the common, nonpathogenic sheep trypanosome T. melophagium. Information on the pathogenicity of the trypanosomes that occur outside of sub-Saharan Africa, primarily in South and Central America, as well as in Asia, is limited. T. cruzi is cyclically transmitted by reduviid bugs in South and Central America, while T. evansi and T. equiperdum are mechanically or sexually transmitted, respectively, in Africa, South and

Table 7.7. Trypanosomosis in various hosts with the emphasis on goats. Species

Cyclically transmitted T. vivax

T. congolense

T. brucei

T. simiae

T. gambiense (West African sleeping sickness)

Morphologic features

Major species affected

Geographic distribution

Vectors involved

Natural infection in goats

Experimental infection in goats

Clinical manifestations in goats

20–27 μm long; monomorphic; short, free flagellum 9–18 μm long; monomorphic; no free flagellum; undulating membrane not seen

Domestic ruminants, camels, horses, antelope All common livestock species and dogs; many wild game species Domestic ruminants, horses, dogs, and cats

Widespread in tropical Africa

Glossina spp.

Common

Readily

Acute and chronic forms; usually mild

Widespread in tropical Africa

Glossina spp.

Common

Readily

Acute, subacute, and chronic forms; mild to fatal outcome

Widespread in tropical Africa

Glossina spp.

Common, but with strain variation

Yes, with strain variation

Acute, rapidly fatal outcomes or chronic infections

Domestic pigs, camels, wild warthogs

Widespread in tropical Africa

Glossina spp. and Stomoxys, Tabanus flies

Uncommon

Not reported

Mainly subclinical or mild clinical disease

Humans

Tropical West and Central Africa

Glossina spp. and various biting flies

Uncommon; goats very resistant

Very difficult

Humans, in addition to species affected by T. brucei Humans

East and Southern Africa

Glossina spp.

Uncommon

Yes

Noninfective or a chronic form leading to death or spontaneous recovery Experimental infections subacute and fatal

South and Central America; sporadic in United States

Reduviid bloodsucking bugs

Not reported

Yes

15–35 μm long; polymorphic; undulating membrane always seen 10–24 μm long; polymorphic; variable undulating membrane Same as T. brucei; slender, intermediate stumpy forms

T. rhodesiense (East African sleeping sickness)

Same as T. brucei and T. gambiense

T. cruzi (Chagas disease)

16–20 μm long; in blood forms undulating membrane and free flagellum moderately well developed; tissue forms resemble Leishmania

No

297

298 Goat Medicine Table 7.7. Continued Species

Morphologic features

Major species affected

Geographic distribution

Vectors involved

Natural infection in goats

Experimental infection in goats

Clinical manifestations in goats

T. uniforme

12–20 μm long; monomorphic; flagellum is free, shorter than T. vivax 50–60 μm long; well defined undulating membrane and free flagellum

Domestic ruminants; antelope

Zaire, Uganda

Glossina spp.

Yes

Not reported

Nonpathogenic or subclinical infection

Goats

Israel

Lipoptena caprina, a hippoboscid fly

Yes

Not reported

Nonpathogenic

Cattle, water buffalo

North, South, and Central America

Various biting flies

Uncommon but reported

Not reported

Not reported

Camels, equines, dogs, water buffalo

India, Far East, Near East, Philippines, North Africa, South and Central America Northern and South Africa, Central and South America, Mexico, Middle East, Italy, former USSR

Various biting flies

Yes

Not reported

Not reported

Venereal transmission

Not reported

Not reported

Not reported

T. theodori

Mechanically transmitted T. vivax viennei

T. evansi (Surra)

15–25 μm long; monomorphic; similar to T. vivax 15–34 μm long; usually monomorphic; same as slender form of T. brucei; occasional stumpy form

T. equiperdum (Dourine)

15–34 μm long; same as T. evansi

Horses

Central America, and Asia. These trypanosomes cause disease in various species. T. cruzi is primarily of importance for humans; T. evansi for camels, horses, cattle, and Asian buffalo, and T. equiperdum for horses. Their infectivity for goats is presumed to be low. Kids infected experimentally with T. cruzi showed no clinical signs of disease and carried the infection for thirtyeight days (Diamond and Rubin 1958). The goat is a natural host for T. evansi, but reports of the disease, surra, in goats are rare. Recently, surra was reported to be occurring in goats in Mindanao in

the Philippines, but field confirmation has been difficult. It is believed that the cases may involve a particularly virulent strain of T. evansi. Experimental challenge of goats with an equine strain of T. evansi from Mindanao produced clinical and pathological changes consistent with surra (Dargantes et al. 2005, 2005a). Epidemiology The distribution and intensity of animal trypanosomosis in sub-Saharan Africa follow the distribution and intensity of the various species of the tsetse fly.

7/Blood, Lymph, and Immune Systems 299

Approximately 10 million km2 or 37% of the African continent is tsetse-infested. This area includes thirtyeight countries. Various estimates suggest that the livestock-carrying capacity of such areas in West and Central Africa could be increased five- to seven-fold by eliminating or controlling animal trypanosomosis (Griffin 1978). There are more than 200 million goats in Africa with 50 million or more in the tsetse-infested regions of the continent. Natural infections with T. congolense, T. vivax, or T. brucei resulting in clinical disease have been known in African goats since the early twentieth century. Until recently, however, the perception has persisted that goats are highly resistant to infection, that caprine trypanosomosis is only sporadic, and that the disease in goats is of little economic consequence (Griffin 1978). This opinion is currently undergoing a critical reappraisal. Regional differences do exist in the prevalence of caprine trypanosomosis, but it can be high in some areas (Kramer 1966; Griffin and Allonby 1979). In general, caprine trypanosomosis is more common in East than West Africa. This is attributed to differences in feeding preferences between riverine species of Glossina and savannah species; the latter are more inclined to feed on goats. A report from Zambia identified T. brucei, T. congolense, and/or T. vivax infections in goats naturally transmitted by Glossina morsitans morsitans and G. pallidipes (Bealby et al. 1996). Goats may serve as a reservoir of trypanosome infection for other species. In the Sudan, goats infected with T. congolense developed a chronic form of disease from which many spontaneously recovered. When the organism was passaged from goats into calves however, acute fatal bovine trypanosomosis occurred (Mahmoud and Elmalik 1977). Goats also have been implicated as a reservoir of T. rhodesiense, a nosodeme of T. brucei transmissible to man (Robson and Rickman 1973). The economic impact of trypanosomosis on goat production is beginning to be studied. A Kenyan analysis demonstrated that goats receiving monthly chemoprophylaxis against trypanosomosis had significantly decreased mortality rates, increased weight gains, and improved reproductive performance compared to untreated control goats. Differences in performance were also noted between breeds in the study, with indigenous breeds performing better than nonindigenous breeds or cross breeds (Kanyari et al. 1983). The existence of inherent trypanotolerance in certain goat breeds has been controversial. It is generally accepted that trypanotolerant breeds of cattle exist, notably the N’dama of West Africa and the West African Shorthorn, and that trypanotolerance is measured by the ability to control trypanosome numbers and resist the effects of the disease, independent of pre-existing immune experience. This inherent ability

to control parasitemia and minimize disease is not as great in specific goat breeds, despite the general observation that some breeds of goats readily survive in tsetse infested areas. Dwarf West African goats may, to some extent, be inherently trypanotolerant, yet they can be readily infected experimentally (Murray et al. 1982). While earlier studies suggested that indigenous goat breeds of East Africa may show inherent trypanotolerance, no evidence of genetic resistance was observed in a subsequent study with either natural or experimental challenge in East African, Galla, or East African goats cross bred with Toggenburg, Nubian, or Galla breeds (Whitelaw et al. 1985). One factor contributing to the perceived trypanotolerance of various goat breeds under field conditions may be the feeding preferences of Glossina spp. Flies may select other livestock over goats when mixed animal populations are present (Murray et al. 1984). The existence of true trypanotolerance in goats deserves additional careful investigation. Pathogenesis Trypanosomes fall into two groups regarding their ability to produce disease. The hematic group, which includes T. congolense and T. vivax, remains confined to the circulation after introduction into the bloodstream by feeding Glossina spp. The disease produced in these infections is characterized by anemia. The humoral group, which includes T. brucei, is more invasive, with trypanosomes found in intercellular tissue and body cavity fluids after initial infection. Anemia in these cases is overshadowed by marked inflammatory, degenerative, and necrotic changes. Anemia in trypanosomosis may be due to extravascular hemolysis and erythrophagocytosis, as well as decreased erythropoiesis in chronic infections (Kaaya et al. 1977). The destruction of red blood cells may result from both non-immune and immune mediated mechanisms. Hemorrhage secondary to disseminated intravascular coagulation (DIC) may also contribute to anemia. Thrombocytopenia, microthrombus formation, and hemorrhage suggestive of DIC have been observed in caprine trypanosomosis due to T. vivax (Van den Ingh et al. 1976; Veenendaal et al. 1976). Anemia may be exaggerated by hemodilution because of expansion of blood and plasma volumes, which increased, respectively, 29% and 44% in goats with subacute T. vivax infection (Anosa and Isoun 1976). The pathogenesis of inflammation and tissue damage by humoral trypanosomes such as T. brucei is complex and is reviewed elsewhere (Soulsby 1982; Connor and van den Bossche 2004). Immunosuppression can occur in trypanosomosis. T. vivax and T. brucei infection of goats resulted in depressed responses to mitogen stimulation in lymphocyte transformation tests (van Dam et al. 1981a; Diesing et al. 1983) and

300 Goat Medicine

goats experimentally infected with T. congolense produced a weaker antibody response to vaccination with Brucella melitensis vaccine than uninfected controls (Griffin et al. 1980). Impaired immune function may aggravate the severity of concurrent infections. This was suggested by evidence of higher mortality rates and parasite loads in goats concurrently infected with T. congolense and Haemonchus contortus than in goats infected with only one parasite or the other (Griffin et al. 1981a, 1981b). Under field conditions, goats with chronic trypanosomosis are more susceptible to helminthiasis and carry heavier helminth burdens, probably as a result of immunosuppression. Trypanosome infection is associated with ovarian dysfunction and irregular estrus cycles (Llewellyn et al. 1987; Mutayoba et al. 1988). Gross testicular atrophy has been reported in bucks with T. congolense infection (Kaaya and Odour-Okelo 1980). There is also a variety of endocrine abnormalities reported following inoculation of trypanosomes into the bloodstream of goats, including depression of circulating thyroxine, testosterone, and cortisol levels (Connor and van den Bossche 2004). One of the most notable features of trypanosomosis is the successive waves of parasitemia that occur every few days in animals that survive initial infection. Each wave of parasitemia is followed by an increase in circulating antibody that temporarily reduces the parasitemia. The effect is only temporary, however, because cyclically transmitted trypanosomes are capable of repeatedly altering their surface antigens and thereby evade the host immune system sufficiently to avoid total elimination of infection. These variant antigens are surface coat glycoproteins. It is the occurrence of variable antigens that has been the major obstacle in the development of effective vaccines. Clinical Signs Clinical syndromes produced by the three major tsetse-transmitted trypanosomes are presented separately below. In the early stage of the disease, a prominent skin chancre may be noted at the site of tsetse fly feeding T. VIVAX. Acute, subacute, and chronic forms of disease can occur. Acute disease usually results in recovery or death within four weeks. Subacute disease, with a decreased level of parasitemia, may persist for ten to twelve weeks, and chronic disease for seventeen weeks or longer. The chronic form of the disease is most common. Parasitemia is evident on blood smear within six to seven days after infection and peaks at approximately ten days, but identification of the parasite on blood smears in subacute and chronic cases is less reliable. Successive waves of parasitemia occur at four- to seven-day intervals, accompanied by fluctuating fevers as high as 108°F (42.2°C). Anemia

develops rapidly, coinciding with the first wave of parasitemia. Clinical signs may include depression, anorexia, lack of rumen motility, enlarged lymph nodes, and weight loss. Anemia can become severe with signs including pallor, increased heart rate and respiration, exercise intolerance, and marked listlessness. Jaundice and hemoglobinuria are uncommon findings. Severe emaciation is evident in chronic disease, although surviving animals may begin to gain weight again and the severity of anemia diminish as the level of recurrent parasitemia is brought under control. T. CONGOLENSE. Acute, subacute, and chronic forms of disease also have been described for T. congolense infection of goats (Griffin and Allonby 1979a). The acute phase results in death or recovery within six weeks. Fluctuating temperatures up to 106°F (41.1°C) occur and in fatal cases anemia is severe. Weight loss is variable, depending on the duration of disease. In recovered animals, fever and a milder anemia may occur with the initial parasitemia, but PCV returns rapidly to normal. In subacute cases, animals die or recover within six to twelve weeks after infection. In fatal cases, cyclic parasitemia persists and fluctuating fever, progressive emaciation, weakness, lethargy, and pallor are evident clinically. Recovering animals begin to gain weight and strength as fever and anemia subside. Chronic infections, lasting twelve weeks or longer, are almost always fatal. Cyclic fever and parasitemia persist, as does the anemia. Animals become emaciated, hair coat becomes rough, superficial lymph nodes are palpably enlarged, and intermandibular and facial edema develop. Animals become recumbent, then comatose, and die. T. BRUCEI. Because T. brucei is a humoral trypanosome, clinical signs may be more severe, although pathogenicity varies with the strain. In addition to anemia, fever, and emaciation, keratitis and signs of encephalitis may occur, including head pressing, circling, and opisthotonos. Lymphadenopathy is a consistent finding and may be more pronounced than with T. vivax or T. congolense infection. The typical course of disease is three to five months, and is usually fatal. Anemia is not as pronounced as it is in infection with the hematic trypanosomes. Parasitemia is also less severe, and detection of trypanosomes on blood smears is more difficult. Examination of lymph node smears may be more rewarding. Clinical Pathology and Necropsy In all forms of the disease, the most significant laboratory findings relate to anemia (Edwards et al. 1956). Moderate to severe decreases in PCV, Hb, and RBC numbers can be seen. In the early stages, anemia is macrocytic, while in chronic and terminal cases, a normocytic anemia is more common. This is reflected in

7/Blood, Lymph, and Immune Systems 301

the bone marrow, which is often hyperplastic in acute disease and normoplastic or hypoplastic in chronic disease. In experimental infection of goats, all species of trypanosomes produced a significant thrombocytopenia with platelet counts 65% to 82% less than the normal mean (Davis 1982). No consistent changes in the leukogram have been noted in caprine trypanosomosis. In cattle, a transient leukopenia and rebound leukocytosis can occur during the acute phase of disease. Serum chemistry values remain normal. Animals with acute trypanosomosis may show laboratory evidence of DIC. There are no pathognomonic lesions in trypanosomosis. In acute cases, necropsy findings include an anemic carcass, general lymph node enlargement, marked splenomegaly, serosal and mucosal petechial hemorrhage, and hydropericardium. Microscopically, lymphoid hyperplasia is pronounced and microthrombi may be evident in vessels of numerous organs. In the hematic forms of disease, trypanosomes is present only in vascular spaces, while with T. brucei extravascular parasites may be seen in tissues such as the cornea and cerebrospinal fluid. In chronic cases, severe emaciation, with serous atrophy of fat, and muscle degeneration may be observed in addition to petechiation, lymphadenopathy, and splenomegaly (Losos and Ikede 1972). Diagnosis Anemia and emaciation in goats from tsetse endemic areas suggest the diagnosis of trypanosomosis. Definitive diagnosis is based on identification of trypanosomes in blood smears or tissues. However, chronic infections in goats are common and trypanosomes may be difficult to find in the blood. In live animals, parasites may be more readily detected in blood samples taken from an ear vein rather than the jugular vein. Thick blood smears examined after lysis of red cells and staining with Romanowsky stain may reveal the presence of parasites, but morphologic identification is better performed on thin smears. Microhematocrital centrifugation of blood and examination of a wet mount of the plasma-buffy coat interface can improve detection. For confirmation of T. brucei infection, examination of smears of lymph node aspirates, and mouse inoculation are preferred methods of diagnosis. Because parasitemia is cyclical, examining smears from numerous animals in a suspect group may improve the chances of diagnosis. Serologic tests employed in the diagnosis of trypanosomosis include an indirect hemagglutination test, a complement fixation test, an indirect fluorescent antibody test, and an enzyme linked immunosorbent assay. Information on interpretation of serologic responses in goats is limited. At present, molecular tools, such as PCR, are commonly employed, but

demand well-equipped laboratories and do not replace classical methods in the field. The differential diagnosis for trypanosomosis should include helminthiasis, malnutrition, and other hemoparasites, notably anaplasmosis, babesiosis, and theilerosis, which occur in trypanosomosis endemic areas. Treatment A variety of trypanocidal compounds are available for treatment, but no new drugs have been marketed for quite some time. Subsequently, drug resistance has become a significant problem. Compounds and dosages are formulated for single-dose use and treatment is usually on a herd wide basis because serial treatments on individual animals are difficult to carry out in the semi-nomadic livestock farming systems prevalent in endemic areas. Several of the drugs are locally irritating, so subcutaneous injections should be given in areas of loose skin, and intramuscular injections given deeply, avoiding vessels and nerves. Curative doses used in cattle are also appropriate for goats and sheep on a mg/kg body weight basis (Ilemobade 1986). Treatment is reviewed by Uilenberg (1998). Diminazene aceturate is given intramuscularly as a 7% cold water solution at a dose of 3.5 mg/kg and is considered effective against the three major trypanosomes. Quinapyramine dimethyl sulfate is little used nowadays, except for treating T. evansi in camels and horses, because of toxicity and drug resistance problems. It is given subcutaneously as a 10% cold water solution at a dose of 5 mg/kg. Relapse of infection has been reported in goats treated with diminazene aceturate, presumably because of re-emergence of trypanosomes from the central nervous system where they were inaccessible to the drug during earlier treatment (Whitelaw et al. 1985a). Homidium chloride (soluble in cold water) or homidium bromide (soluble in hot water) are given in a 2.5% water solution at a dose of 1 mg/kg intramuscularly and are effective against T. vivax and T. congolense. Isometamidium chloride is currently the most commonly used drug in ruminants. It is effective against the hematic trypanosomes when given at a dose of 0.25 to 0.75 mg/kg intramuscularly as a 1% or 2% solution in water. This drug was shown to produce signs of shock or death in goats if given intravenously at doses greater than or equal to 0.5 mg/kg (Schillinger et al. 1985). All drugs of the phenanthridinium group (homidium and isometamidium compounds) are potentially carcinogenic and should be handled as such. Control There are numerous constraints on control, including reservoirs of infection in wild animal populations,

302 Goat Medicine

the ability of trypanosomes to continuously alter their antigenic character and thus confounding the development of suitable vaccines, a limited availability of effective drugs, the development of resistance to existing trypanocidal drugs, the difficult logistics of widespread tsetse control, lack of economic resources, poorly developed animal disease control programs, limited technical training programs, lack of international cooperation, and political instability (Doyle et al. 1984; Murray and Gray 1984). Currently, the major fronts in trypanosomosis control in sub-Saharan Africa are reduction or elimination of tsetse populations and chemoprophylaxis of livestock. Tsetse fly control is accomplished by several methods, alone or in combination, including ground or aerial application of insecticides such as chlorinated hydrocarbons and synthetic pyrethroids; tsetse trapping with odor baited, insecticide impregnated traps; and gamma-irradiated sterile fly release. Aerial spraying of insecticides is now less commonly employed for environmental reasons, and trapping has emerged as a viable alternative, albeit for more restricted areas of control. Isometamidium chloride protects against infection with the three major goat trypanosomes for two to four months. The prophylactic dose of isometamidium is 0.5 to 1 mg/kg bw administered intramuscularly in a 1% or 2% cold water solution. Earlier chemoprophylactic drugs (pyrithidium and quinapyramine chloride) have been discontinued. Despite intensive research, no effective vaccine is likely in the future because of the continuing problem of antigenic variation in trypanosomes and antigenic strain differences. Given the obstacles to vaccination, there is a keen interest in identifying and promoting trypanotolerant breeds of livestock in endemic areas, as discussed above in the section on epidemiology.

TOXICOLOGICAL DISEASES Copper Poisoning Primary copper poisoning has been reported in the goat, but is not common. It can produce a severe hemolytic anemia with hemoglobinuria and death as occurs in the more commonly affected ruminants—sheep and young cattle. Epidemiology There is a marked difference in susceptibility between sheep and goats regarding chronic copper poisoning. The condition is harder to produce experimentally in goats than in sheep (Søli and Nafstad 1978; Solaiman et al. 2001), and published reports of naturally occurring caprine copper poisoning are rare. In sheep, several naturally occurring forms of the disease

are recognized, including acute copper poisoning, primary chronic copper poisoning, secondary phytogenous copper poisoning, and secondary hepatogenous copper poisoning. Only the acute and primary chronic forms of copper poisoning have been reported to occur naturally in goats. The acute form was reported from Israel (Shlosberg et al. 1978) and involved the oral administration of copper sulfate solution to goats as an anthelmintic. Chronic cases have been reported from New Zealand and the UK, and involved young, handreared Angora goats exposed to a variety of coppercontaining feeds and supplements (Belford and Raven 1986; Humphries et al. 1987). More recently, primary chronic copper poisoning was reported in dairy goats in the United States (Cornish et al. 2007). Etiology and Pathogenesis Acute copper poisoning is sporadic in occurrence and results from an accidental or unintentional ingestion of abnormally high doses of inorganic copper over a short period. Sources of copper include copper sulfate foot baths, improperly mixed feedstuffs or mineral supplements, or inappropriate administration of copper salts for therapeutic purposes. In acute copper ingestions, direct irritation of the gastrointestinal mucosa causes many of the clinical signs observed, including abdominal pain, vomiting, and shock. Death may precede the development of hemolytic anemia. Animals that survive the initial gastrointestinal insult subsequently absorb sufficient copper to initiate hemolysis. Acute copper poisoning can be induced in sheep and young calves with a single oral dose of copper in the range of 20 to 110 mg/kg bw. The dose is similar in goats, with acute copper toxicity observed after an oral dose of approximately 60 mg/kg of copper sulfate (Shlosberg et al. 1978). Experimentally, acute toxicosis was produced in goats within three to four days by three daily intravenous injections of CuSO4 . 5H2O at a total daily dose of 50 mg (Wasfi and Adam 1976). In all forms of chronic copper toxicity, the ultimate pathway for clinical disease is thought to be the same. Ingested copper accumulates in the liver over time until maximum hepatic levels are reached, at which point there is a sudden release of the accumulated copper into the blood, initiating an acute hemolytic crisis (Radostits et al. 2007). However, this notion may require reconsideration as a recent, well documented herd outbreak of primary chronic copper toxicosis in a dairy goat herd did not involve hemolysis as part of the clinical presentation in affected goats (Cornish et al. 2007). In primary chronic copper poisoning, copper is ingested continuously as part of the regular ration. The level of copper may be, but need not be, abnormally high, because the uptake of copper from the rumen and subsequent accumulation in the liver are condi-

7/Blood, Lymph, and Immune Systems 303

tioned by the concentrations of other minerals present in the ration. Low dietary levels of molybdenum, zinc, calcium, and sulfates can permit excessive uptake and accumulation of otherwise normal dietary levels of copper. In secondary phytogenous chronic copper poisoning, grazing of specific pasture plants, notably subterranean clover (Trifolium subterraneum), promotes the accumulation of copper in liver although the plants themselves are relatively low in copper and do not produce any liver damage. The mechanism behind this phenomenon is not known, but British breeds of sheep and Merino crosses seem more susceptible. This syndrome has not been reported in goats. In hepatogenous chronic copper poisoning, hepatotoxic plants are ingested and produce liver damage that increases hepatocyte affinity for copper accumulation. This can accelerate the development of hemolytic crisis even when dietary levels of copper are within normal limits. Plants most often involved are Heliotropium europaeum and other pyrrolizidine alkaloid containing species, including Senecio spp. and Echium plantagineum. This syndrome has not been reported in goats. In fact, goats are relatively resistant to the effects of Senecio, and the use of goats has been proposed to clear rangelands of the plant to make them suitable for grazing by cattle (Dollahite 1972). Primary chronic copper poisoning can be induced in sheep with daily oral doses as low as 3.5 mg/kg bw, but goats require more aggressive challenge. In one study, oral administration of CuSO4 . 5H2O twice daily at a dose of 20 mg/kg of bw for fifty-six days produced hemolytic crisis in only one of three Norwegian breed goats. At necropsy, liver copper levels were 1,168 ppm wet weight and kidney levels were 635 ppm wet weight. There were no hemolytic crises in the two other goats killed after seventy-three and 113 days of daily dosing. Liver copper levels of 314 and 384 ppm wet weight and kidney levels of 3 and 4.5 ppm, respectively, were recorded (Søli and Nafstad 1978). In contrast, sheep are reported to experience hemolytic crises when liver copper levels exceed 150 ppm wet weight (Sanders 1983). In another study with Nubian goats, neither of two goats given CuSO4 . 5H2O daily at 20 mg/kg/bw developed hemolytic anemia, while one of two given 40 mg/kg/day and one of two given 80 mg/kg/day did (Adam et al. 1977). In a more recent experimental study, Nubian goats were fed supplemental copper at increasing levels from 100 mg/head/day up to 1,200 mg/head/day for up to thirty-five weeks. Only individuals receiving 600 mg/head/day or higher showed a clinical effect, with signs of thirst, diarrhea, dehydration, lethargy, and weight loss. However, none experienced hemolytic anemia. The authors report that daily doses of copper of 100 mg/head/day are suffi-

cient to produce clinical toxicity in sheep and conclude that goats are more resistant to copper toxicity than sheep (Solaiman et al. 2001). It has been postulated that the difference in susceptibility of sheep and goats to copper poisoning is a function of differences in the distribution of copper- and zinc-binding soluble hepatic proteins (Mjor-Grimsrud et al. 1979). In goats, as in sheep, development of copper toxicity may be conditioned by influences of other elements. Goats pretreated with vitamin E and selenium injections developed hemolytic crisis after fifty days of oral dosing with 15 mg/kg of copper as copper sulfate, while animals receiving the same copper dose with no vitamin E or selenium pretreatment showed no clinical signs after the same period. Goats with evidence of hemolytic crisis had decreased liver levels of reduced glutathione and higher glutathione disulfide levels (Hussein et al. 1985). Clinical Signs Acute copper poisoning in goats resulting from oral ingestion of copper produces signs of gastrointestinal irritation including evidence of abdominal pain, grinding of the teeth, frothing at the mouth, vomiting, and diarrhea. Additional signs include labored breathing, muscle fasciculation, tachycardia, and increased amplitude of heart sounds. Within six hours, severely affected animals may collapse and die. Morbidity and mortality rates are dose-dependent. Mortality rates as high as 53% have been reported in goats given oral copper sulfate at a dose of 60 mg/kg. In cases of chronic copper toxicity and acute toxicity associated with parenteral administration of copper, dullness, anorexia, thirst, dehydration, and elevated heart and respiratory rates are early signs. Diarrhea may also be present. If hemolytic anemia is part of the clinical syndrome, then icterus will be noted on mucous membranes, serum will be pink, and urine red-brown. Dyspnea may develop as a result of severe anemia, and death may occur in twenty-four to forty-eight hours after the onset of signs. In untreated animals surviving longer, anuria and uremia may develop as a result of hemoglobinuric nephrosis. However, in the most recent report of chronic copper toxicosis in a dairy goat herd (Cornish et al. 2007), none of the affected animals showed indications of hemolytic anemia. Only lactating does were clinically affected though young goats had laboratory evidence of copper levels consistent with intoxication. Clinical signs in lactating does included anorexia, agalactia, dullness, dehydration, teeth grinding, and drooling. Affected does progressed to recumbency and showed neurologic abnormalities such as paddling and vocalization followed by death. Signs associated with hemolytic anemia such as icterus or hemolyzed plasma were absent (Cornish et al. 2007).

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Clinical Pathology and Necropsy During the acute hemolytic crisis, PCV may fall below 10%, and RBC and Hb levels drop correspondingly. Heinz bodies can be seen in RBCs and there may also be methemoglobinemia. Serum bilirubin is markedly elevated and the urine is strongly positive for hemoglobin. Alterations in clinical chemistry are consistent with liver damage, and elevations of aspartate aminotransferase (AST), gamma glutamyl transferase (GGT), sorbitol dehydrogenase (SDH), and blood ammonia are reported in the goat, though the magnitude of increase is highly variable. Elevation in liver enzymes may precede the acute hemolytic crisis by several weeks and this may be helpful for screening animals in a herd not yet showing clinical disease. None of these changes are diagnostic for copper poisoning and it is important to establish the presence of abnormally elevated copper levels in blood, liver, kidney, or other tissues to confirm the diagnosis. In a recent report of field cases of primary chronic copper toxicity, it was noted that in clinically affected goats there was no clear association between the magnitude of increase of serum hepatic enzymes and the concentrations of copper in the serum or liver. In clinically unaffected, younger does in the same herd, there was no consistent relationship between serum hepatic enzyme activities, serum copper concentration, and liver copper concentration. It was concluded that serum liver enzymes and serum copper levels are insensitive markers of liver copper concentration and the definitive method for diagnosis antemortem is to measure copper concentrations in liver samples obtained by biopsy (Cornish et al. 2007). Another study confirmed the reliability of liver as the optimal sample for establishing copper toxicosis and pointed out that hair samples did not reflect the copper status of animals (Solaiman et al 2001). Normal liver copper levels are reported in the range of 0.188 to 1.805 μmol/g (12 to 115 ppm) (MjorGrimsrud et al. 1979). The normal kidney copper level in goats has been reported as 0.1 μmol/g (6.4 ppm). Normal serum copper levels in goats are reported to be in the range of 9.4 to 23.6 μmol/L (60 to 150 μg/dl, or 0.6 to 1.5 ppm) (Underwood 1981). In field cases of chronic copper toxicity in goats in New Zealand, plasma copper levels of 34.6 μmol/l (219.8 μg/dl or 2.2 ppm) and red blood cell copper levels of 95.8 μmol/l (608.6 μg/dl or 6.1 ppm) were observed during acute hemolytic crisis. Liver copper levels were as high as 21.4 μmol/g dry matter (1359 ppm), and kidney levels as high as 6.4 μmol/g dry matter (406 ppm) (Humphries et al. 1987). In experimental chronic copper intoxication in goats, animals with hemolytic crises had liver copper levels more than 900 ppm and kidney copper levels more

than 170 ppm. Goats that were fed excessive copper but did not develop hemoglobinuria had liver copper levels between 300 and 1,100 ppm and kidney levels between 3 and 150 ppm while a control goat not fed copper had liver copper levels of 18.5 ppm and kidney levels of 6.7 ppm (Adam et al. 1977; Søli and Nafstad 1978). In acute copper toxicity of goats, animals dying shortly after ingestion had normal liver and kidney levels of copper, but the copper contents of rumen ingesta and feces were elevated to 225 ppm and 1,060 ppm, respectively. Findings at necropsy may include thin, watery blood and general icterus. The liver is enlarged, friable, and yellow. The kidneys are swollen, dark brown to black, metallic, and softened. Hemorrhages on the epicardium and endocardium and congestion of the lungs and spleen may be noted. In acute oral intoxication, marked inflammation of the abomasal and intestinal mucosae is evident. Histologically, the liver lesion is characterized by hemosiderin deposits, centrilobular necrosis and fatty degeneration, and biliary hyperplasia. The kidney exhibits lesions of nephrosis with casts present in tubules. One experimental study of chronic copper poisoning in the goat resulted in liver lesions atypical for the disease and it was suggested that the pathogenesis of chronic copper poisoning in the goat may differ from that in the sheep (Søli and Nafstad 1978). Others have consistently described lesions found in the goat to be similar to those found in sheep. Diagnosis When signs of abdominal pain are prominent—as in acute copper toxicosis—intestinal accidents, urethral obstruction, and early infectious enteritis must be considered. When hemolytic anemia is present, the differential diagnosis for chronic copper toxicity in the goat includes the hemoparasites babesiosis and trypanosomosis, where they occur, and several plant poisonings that could lead to hemolytic anemia, particularly kale, which also can produce Heinz bodies. Other intoxications must be ruled out in acute copper toxicity, including arsenic ingestion, organophosphate toxicity, cyanide poisoning, and nitrate poisoning. The recent report of goats with chronic copper toxicosis which had no evidence of hemolytic anemia but did have elevated liver enzymes and neurological signs suggests that various causes of hepatic encephalopathy may have to be considered in the differential diagnosis of chronic copper toxicity. Treatment Treatment is directed at the clearance and elimination of copper from the blood and tissues through the use of chelating agents. Until recently, the only treatment reported specifically in goats was ammonium tetrathiomolybdate, administered intravenously at a

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dose of 1.7 mg/kg for three treatments on alternate days (Humphries et al. 1987). In lambs, a daily oral total dose of 100 mg of ammonium molybdate in combination with 1 g of sodium sulfate given for as long as three weeks has been effective in reducing tissue copper concentrations, and may prevent or ameliorate hemolytic crisis. Other chelating agents also have been used, including oral d-penicillamine at a dose of 52 mg/kg daily for six days. A recent report describes the successful use of penicillamine, ammonium molybdate, and sodium thiosulfate in the treatment of adult goats with primary chronic copper toxicosis (Cornish et al. 2007). Penicillamine was given orally at a dose of 50 mg/kg bw every twenty-four hours for seven days, ammonium molybdenate orally at a total dose of 300 mg every twenty-four hours for three weeks, sodium thiosulfate orally at a total dose of 300 mg every twenty-four hours for three weeks. Vitamin E was also given orally at a total dose of 2,000 U every twenty-four hours for three weeks as an anti-oxidant. Penicillamine is expensive and, though effective, its use may be limited in commercial herds by cost considerations. Therapeutic consideration should also be given to management of anemia when present as well as management of potential nephrosis in severely affected individuals. Blood transfusion might be indicated in exceptional cases when PCV is perilously decreased. Continuous intravenous administration of balanced electrolyte solutions helps maintain urine outflow and reduce the potential for irreversible hemoglobinuric nephrosis. Control Control of acute copper poisoning in the goat depends on common sense to avoid accidental exposure to and ingestion of high doses of copper. Because chronic copper poisoning in goats is rare, aggressive control methods such as fertilization of crop and grazing lands with molybdenum and molybdenum supplementation of feed are probably unnecessary. However, some caution should be exercised in using feedstuffs formulated for cattle, especially calf milk replacers used in kids. Nutritional requirements for copper in goats are discussed in Chapter 19. Kale Anemia (Brassica Poisoning) The use of kale (Brassica oleracea) as a feedstuff for ruminants may lead to the development of Heinz body anemia with possible mortality. Cattle are most susceptible, and sheep least susceptible. Goats have an intermediate position. Epidemiology Clinical outbreaks of Heinz body anemia have occurred in ruminants when kale has a predominant

role in feeding programs. This has been a notable problem in Great Britain and Germany. Consumption of large amounts for extended periods increases the likelihood of disease, and anemia rarely develops until animals have been consuming kale for one to three weeks. Mature plants and plants with secondary growth are more toxic. The consumption of plants that have been frosted or frozen also increases the likelihood of disease. Certain varieties of kale are more toxic than others, but heating or ensilage destroys the toxic principle. The condition is reproducible experimentally in goats (Greenlagh et al. 1969, 1970; Smith 1980). It has been reported as a cause of mortality in Angora goats in New Zealand (Anonymous 1988). Affected goats had been grazing the kale for less than two weeks, while lambs that had preceded kids in grazing were unaffected. It was suspected that kids, already anemic from haemonchosis, were more severely affected by kale toxicity. Etiology and Pathogenesis Kale contains high levels of S-methyl cysteine sulfoxide that is converted by rumen bacteria to dimethyl disulfide. This is then absorbed from the rumen and induces Heinz body anemia via the oxidation of hemoglobin in circulating red blood cells. Mature red blood cells are more susceptible to oxidation than young cells so that the anemia may become temporarily selflimiting as the regenerative response increases the relative proportion of young cells to old. As these cells mature, the anemia may worsen again if kale continues to be fed. This phenomenon is associated with higher levels of glutathione reductase in young cells that are protective against oxidation of hemoglobin (Smith 1980). Clinical Findings After one to three weeks of kale ingestion, goats develop a marked anemia. Sudden death may be the first reported sign in an affected herd or flock. Closer inspection may identify additional animals that hang back from the flock, appear weak, and have pale mucous membranes. Additional signs include inappetence, tachypnea, and tachycardia. Red-brown urine may be noted because of hemoglobinuria. Clinical Pathology and Necropsy Anemia may be pronounced, as hemoglobin levels can decrease below 6 g/dl and sometimes as low as 3 g/dl, with a concomitant decline in RBCs counts and PCV. The appearance of Heinz bodies in RBCs in the peripheral blood may precede the decrease in Hb by as much as a week. Methemoglobinemia, sometimes observed in cattle, is rare in goats. The anemia is

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regenerative, and reticulocytes and an increase in MCV can be noted. Necropsy findings specific for the goat have not been reported. In other species, post mortem lesions include pallor, hemoglobinuria, thin, watery blood, dark kidneys, and congestion of the liver with moderate hepatic necrosis. Jaundice, especially of the subcutaneous fat, is pronounced. Diagnosis Diagnosis is presumptive based on the presence of Heinz body anemia in conjunction with a history of kale feeding. In other ruminants, rape (Brassica napus), wild onion (Allium validum), cultivated onion, and stubble turnip consumption also produce Heinz body anemia. When widespread jaundice is noted at necropsy, chronic copper toxicity and leptospirosis must be considered in the differential diagnosis. Treatment and Control Therapy is limited to supportive care and the possibility of blood transfusion. Removal of kale from the diet results in a return of normal Hb levels within two to three weeks. Affected goats should not be subjected to stress or vigorous exercise during the recovery. Other Plant-related Anemias Several reports identify plants toxic to goats with anemia as a clinical manifestation. Acanthospermum hispidum, a weed of the Compositae family, has been associated with livestock poisoning in the Sudan, and its toxicity for goats has been confirmed experimentally. Animals fed the plant at a dose of 5 g/kg bw daily showed anorexia, jaundice, and diarrhea within one week, followed by dullness, dyspnea, weakness of the hind end, and terminal neurologic signs, probably because of hepatoencephalopathy. Clinical pathology indicated acute liver dysfunction and development of a marked hemolytic anemia during the course of disease (Ali and Adam 1978). Ipomoea carnea, in the family Convolvulacae, is a tropical plant with strong drought-resistant properties; it may be an abundant source of browse for goats during adverse climatic periods. Toxicity in goats because of Ipomoea spp. has been presumed or documented in India, Brazil, and the Sudan (Tirkey et al. 1987; Dobereiner et al. 1987; Damir et al. 1987). Experimentally, daily repeated doses of fresh leaves of Ipomoea carnea as low as 5 g/kg of bw can produce a clinical syndrome of inappetence, depression, pallor, weakness of the hindquarters, dyspnea, weight loss, and death within three weeks, although there is individual variation in response, and some goats survived for longer than three months. A moderate, normocytic,

normochromic, occasionally hypochromic anemia is observed in severely affected goats. Packed cell volumes as low as 15% occur, with Hb as low as 5 g/dl. In acute cases, the anemia is nonregenerative, but in animals that survived for longer periods, a macrocytic response was observed. Serum chemistry analysis suggested liver dysfunction with elevated AST and ammonia and hypoproteinemia (Tartour et al. 1974; Damir et al. 1987). Toxicity from Ipomoea carnea is dose dependent. In an Indian study, no clinical signs or laboratory abnormalities occurred in goats fed an aqueous extract of the plant at a dose of 160 mg/kg, considered to be one-fifth the LD50 dose (Tirkey et al. 1987). Anemia also has been reported as an incidental finding in several plant poisonings in the Sudan, including Capparis tomentosa (Ahmed and Adam 1980), Tephrosia apollinea (Suliman et al. 1982), and experimentally, Solanum dubium. The latter plant is not routinely eaten by goats but may be consumed during periods of drought (Barri et al. 1983). Bracken fern (Pteridium aquilinum) ingestion has been associated with a number of clinical syndromes in cattle and sheep, including depression of bone marrow activity leading to aplastic anemia, leukopenia with secondary bacterial infections, and ecchymoses secondary to thrombocytopenia, as well as ruminal papillomatosis, progressive retinal degeneration, and enzootic hematuria. There is only one clinical report associating exposure to bracken fern with disease in goats (Tomlinson 1983). Affected goats showed a marked anemia and high fevers that responded to antibiotic therapy, suggestive of secondary bacterial infections. Leukocyte counts and bone marrow evaluations were not performed. The goats concurrently experienced severe gastrointestinal helminthiasis and the contribution of bracken fern ingestion to the anemia and infections was not well established. Currently goats should be considered potentially susceptible to bracken fern toxicity. A report from Venezuela states that bracken fern can cause permanent blindness in goats (Alonso-Amelot 1999). A number of plants have been associated with hemoglobinuria in sheep, including privet (Ligustrum spp.), broom (Cytisus spp.), hellebore (Helleborus spp.), Ranunculus spp., Colchicum spp., and frosted turnips (Kimberling and Arnold 1983). Currently, there are no reports of toxicity with these plants in goats, but it is reasonable to assume that a toxic potential exists.

DISEASES OF THE IMMUNE SYSTEM Thymoma Neoplasia is comparatively uncommon in goats, but thymoma is one of the two most commonly recognized

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caprine tumors. It occurs more frequently in goats than in other domestic species. The other common tumor is the adrenal cortical adenoma seen in castrated male goats, as discussed in Chapter 13.

eight-year-old castrated male French Alpine goat with a history of progressive weight loss, exercise intolerance, and anorexia (Olchowy et al. 1996).

Epidemiology

Lymphosarcoma involving the thymus occurs rarely in goats and must be differentiated from thymoma. In thymoma, the principle neoplastic cell is a polymorphic epithelial cell that is often spindle-shaped, but can be round or ovoid. Lymphocytes are present in thymomas, and may predominate, but they do not exhibit characteristics of neoplastic transformation. The neoplastic cell in lymphosarcoma is the lymphocyte. Because it often produces peripheral lymphadenopathy, lymphosarcoma is discussed in more detail in Chapter 3.

Thymoma is rarely seen in goats younger than two years of age. There is no sex predilection. Because thymomas rarely produce clinical disease, recognition of thymoma in goats has come mostly from slaughterhouse surveys and as an incidental finding in necropsy studies. The highest prevalence has been reported in a group of Saanen goats used for slow virus research studies. Seventeen of ninety-two goats (18.5%) had thymomas at necropsy, with a prevalence of 25.3% in goats older than two years of age (Hadlow 1978). Slaughterhouse surveys indicate a lesser prevalence in general goat populations, with eight cases per 100,000 goats in one study and fourteen of 2,600 adult Angora goats in another, but this is still more than the prevalence of thymoma in other livestock species (Streett et al. 1968; Migaki 1969). Clinical Findings Most occurrences of thymoma are subclinical, but occasionally thymomas have been associated with clinical disease. Congestive heart failure secondary to thymoma was recorded in two aged Nubian goats (Rostkowski et al. 1985). These cases are discussed in more detail in Chapter 8. There is also a case of megaesophagus in an eight-year-old Saanen doe secondary to a thymoma and an associated hematoma which put pressure on the thoracic esophagus. The goat presented with a history of recurrent tympany and regurgitation after eating (Parish et al. 1996). Occasionally, the thymoma may produce a pronounced subcutaneous swelling visible at the base of the neck. Normal thymic tissue is commonly found near the thyroids and at the base of the neck in healthy goat kids, as discussed in Chapter 3. In other species, notably the dog, thymoma has been associated with myasthenia gravis and polymyositis. Clinical Pathology and Necropsy The majority of thymomas occur in the cranial mediastinal cavity and occasionally at the thoracic inlet. Tumor size is variable, with some weighing up to 600 g. The tumors are encapsulated, firm, and grayish-white, and the larger ones tend to be lobulated. On cut surfaces they can contain areas of hemorrhage, cysts, and focal yellow areas of necrosis, sometimes associated with calcification. Metastases are rare, but adhesions to adjacent structures, especially lungs, do occur. In one report, pulmonary metastases from a thymoma were identified in an

Diagnosis

Treatment and Control Currently there are no methods of control. The reported high incidence of thymoma in Saanen goats used in slow virus research suggests that either genetic or viral factors may play a role in the development of caprine thymoma. This merits additional investigation, particularly because the retroviral disease CAE is now recognized to be widespread in goats. Failure of Passive Transfer (FPT) of Maternal Immunity Newborn goats, like the young of other livestock species, depend on the ingestion of antibody-rich colostrum shortly after birth to provide passive immunologic protection until they can actively produce their own array of protective antibodies. The failure to absorb adequate antibodies in the immediate post partum period predisposes young goats to serious infectious disease problems and high mortality rates. Epidemiology Unacceptably high levels of death loss in young goats are recognized as a major constraint on goat production wherever goats are raised. The factors contributing to kid death in various goat-producing regions of the world have been reviewed (Sherman 1987; Morand-Fehr 1987). In extensive management systems, kid losses have been reported in the range of 10% to 60% and, in intensive management systems, from 8% to 17%. These deaths most frequently occur in the first few days of life. Numerous factors contribute to this bias toward early death, including low birth weight, premature delivery, large litter size, poor mothering ability, and environmental and weather conditions at the time of kidding. However, the failure to suckle adequate colostrum at birth contributes significantly to the preponderance of early kid deaths, most likely through the mechanism of failure of passive

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transfer of humoral immunity, as discussed below under pathogenesis. In a French survey, 92% of colostrum-deprived kids that died did so within two days of birth (Morand-Fehr et al. 1984). In an Indian study, serum immunoglobulin (Ig) levels were measured in newborn kids eighteen hours after ingestion of colostrum and the mean serum Ig concentration of these kids was determined to be 735 mg/dl. In the next two months, mortality rates of kids with serum Ig levels less than the mean was 44% but was only 3.8% for those with serum Ig levels more than the mean (Nandakumar and Rajagopalaraja 1983). In addition to providing immunity against infectious disease and reducing neonatal mortality, there are indications that consumption of adequate colostrum by the neonate is associated with other long term benefits. There are positive correlations between serum IgG concentration at twenty-four hours of age (sIgG24) and weaning weight in beef calves as well as positive correlations with first lactation milk production and milk fat content in dairy heifers. In goats, a significant correlation is reported between sIgG-24 and average daily weight gain in preweaned dairy goat kids measured up to thirty days of age (Massimini et al. 2007). Etiology and Pathogenesis The syndesmochorial (epitheliochorial) placentation of the goat does not permit the transfer of Ig from the maternal circulation to the fetus during gestation. Therefore, the kid is born in an agammaglobulinemic state, and though immunocompetent, is highly susceptible to infection because of the immediate lack of circulating humoral antibody. Passive immunization of the newborn kid depends on early oral ingestion of colostrum containing maternally produced Ig. The doe experiences an increase in antibody production, notably of the IgG1 class, in the weeks preceding parturition, and IgG1 antibodies are preferentially transported into the colostrum, aided by the affinity of the Fc fragment of IgG1 for receptors on mammary epithelial cells. The mean concentrations for IgG1 and IgG2 in doe serum are reported as 10.9 and 9.1 mg/ml, respectively, while in colostrum the relative mean concentrations are 50.8 mg/ml for IgG1 and 2.3 mg/ml for IgG2 (Micusan and Borduas 1977). The newborn kid, upon ingesting colostrum, is capable of transporting intact Ig molecules out of the intestinal lumen and into the blood circulation. Survival of intact antibody molecules in the gut lumen probably depends on the presence of trypsin inhibitors present in colostrum. The mechanism of transintestinal transport is pinocytosis through the original neonatal intestinal epithelial cells. It is presumed that as these cells are sloughed and replaced in the normal process by new epithelial cells, the capacity for additional

pinocytosis and additional intestinal absorption of Ig is lost. In the calf and lamb, maximal absorptive capacity is believed to persist for six hours after birth, with all absorptive capacity absent by twenty-four hours of age, although this is conditioned to some extent by extrinsic factors such as the time of first suckling. In contrast, the kid may be able to effectively absorb antibody for a longer period, perhaps as long as four days. In one study, kids fed milk only at birth and not given colostrum until seventy-two hours old demonstrated increased serum antibody levels after colostrum administration. The level achieved, however, was not as much as that observed in kids receiving colostrum at birth, and mortality rates were higher (Vihan and Sahni 1982). Therefore, the potentially longer period for intestinal absorption of colostral antibodies in kids is no reason for delaying the ingestion of colostrum. The fact that the concentration of antibody in colostrum decreases rapidly after the first six to twelve hours also underscores the importance of early ingestion. A number of factors influence the ultimate level of Ig reaching the serum of the kid and the immunity derived from it. Most of these considerations have been elucidated specifically for the lamb but are also considered applicable to the kid (Levieux 1984). These include the ability of the kid to suckle early after birth, volume of colostrum available, absorptive potential of the kid, concentration of antibody in the colostrum, and diversity and activity of the antibody. Small kids, especially if weakened by dystocia, may be unable to rise and therefore experience delayed suckling. Severe weather, disturbance of the doe and kid after birth, and competition by litter mates may also delay suckling or reduce the amount of colostrum available. Normal kids should stand and suckle within approximately one-half hour after birth. The ability of kids to absorb Ig after ingestion of colostrum depends primarily on the time of colostrum ingestion, with earlier ingestion promoting better absorption. Birth weight and length of gestation are reported to be negatively correlated with absorption of Ig. However, there are apparently other unknown factors that affect the intrinsic ability of individual kids to absorb Ig. When newborn kids were administered colostrum from a common source on a per weight basis at the same time interval after birth, serum antibody levels subsequently varied by as much as a factor of eight. In addition to kid factors, maternal factors affect absorption. The concentration and character of Ig in does can also vary. Older does are likely to have a wider immunologic experience than young does and provide a more diverse spectrum of protective antibodies to kids. Breed variation has been observed in both ewes and does (Nandakumar and Rajagopalaraja 1983a; Levieux 1984). In the dairy breeds, where colos-

7/Blood, Lymph, and Immune Systems 309

trum is produced well in excess of that required by offspring, IgG concentrations in the colostrum and subsequently in the kids’ serum can be present in levels considerably higher than those reported for nondairy breeds. The majority of ingested antibody, primarily IgG1, is absorbed across the intestinal tract to become circulating humoral antibody. Therefore, the key protective role of colostral antibody is prevention of general infection, and the most common cause of death in colostrum-deprived kids is colisepticemia. Doe colostrum also contains small amounts of IgA and IgM, 1.7 mg/ml and 3.8 mg/ml, respectively, but the role of colostral antibody in protecting against local, mucosal infection, particularly in the gut, is rather limited. While absorbed antibody is clearly beneficial to the kid in terms of immediate disease protection, passive antibody can have a retarding effect on the development of the kid’s own active immunity. Experimental evidence demonstrates that in colostrum-deprived kids, circulating IgG2 appears earlier in the serum than in colostrum-fed kids and that by twelve weeks of age, circulating levels of both IgG1 and IgG2 are higher in colostrum-deprived kids than colostrum-fed kids (Micusan et al. 1976). Based on studies of the disappearance of antibodies specific for Corynebacterium pseudotuberculosis from kid serum after colostrum ingestion, the half-life of passively acquired antibody is approximately twelve days, with some antibody still detectable in most kids between five and six weeks of age (Lund et al. 1982). Persistent antibodies may inhibit active immunization with homologous vaccines. When colostrum-fed kids were immunized with human gamma globulin, a protein with which their dams had been previously immunized, they showed no measurable antibody response to immunizations at birth and four weeks of age and responded only at eight weeks of age when passive antibody levels to the protein had diminished (Micusan et al. 1976). These observations are of practical concern when planning vaccination schedules for young goats. Clinical Findings There are no specific clinical signs of FPT per se. The condition is suggested by kid deaths occurring within forty-eight hours of birth, in association with clinical signs of septicemia. These include acute collapse, very high or subnormal body temperature, cold extremities, congested mucous membranes, rapid heart rate and thready pulses, and dehydration. Evidence of navel infection, diarrhea, or swollen joints may also be suggestive of septicemia, but many kids die before these signs are observable. Hyperesthesia, seizure activity, or ophistotonos may be observed because of bacterial invasion of the central nervous system or concomitant

acidosis. Pneumonia, enteritis, or a pneumoenteritis complex occurring in kids during the first few weeks of life is also suggestive of FPT. A careful history should be taken to determine if the affected kids were observed to suckle, the time of suckling, whether the caretaker provided colostrum by bottle, and whether navels were disinfected after birth. Examination of the kidding and housing areas for evidence of poor sanitation and lapses in good management technique may suggest that septicemia secondary to FPT is involved. Clinical Pathology and Necropsy The most direct method for determining if FPT is involved in death losses is to measure circulating Ig levels in the serum or plasma of kids. The optimal time for obtaining serum samples from kids is between twenty-four and forty-eight hours of life, because maximum antibody absorption from the gut will have occurred during that time. Methods reported specifically for determination of serum Ig in kids are limited compared with other livestock species. Documented tests include a quantitative zinc sulfate turbidity test and a qualitative glutaraldehyde coagulation test (Vihan 1989; Sherman et al. 1990). Using the zinc sulfate turbidity test, kids receiving 480 ml of heat-treated goat colostrum in the first twenty-four hours of life had mean Ig levels of 1.5 gm/dl when tested twenty-four hours after the last colostrum feeding. Using the glutaraldehyde coagulation test, serum from kids with Ig levels less than 1 gram/dl did not clot after sixty minutes incubation with 10% glutaraldehyde solution. Recently, the use of total protein determination by refractometry and a sodium sulfite precipitation test have been described for deriving reliable estimates of Ig levels in kids under field conditions (O’Brien and Sherman. 1993). When FPT was defined as a serum IgG < 1,200 mg/dl, all cases of FPT were indirectly identified using total protein determination by refractometry when the cutoff for total protein was set at 5.4 g/dl. Currently, commercial test kits are also available for direct measurement of IgG in goat serum using radial immunodiffusion (Massimini et al. 2007). Studies correlating antibody level to morbidity and mortality in kids are scarce compared with similar work for calves, lambs, and foals, so minimal acceptable levels of circulating Ig for kids under different systems and conditions of management are not established. In a recent prospective study of kid survival in relation to circulating Ig levels in intensively managed dairy goat kids in New England, in the United States, a serum Ig level of 1,200 mg/dl appeared to be protective (O’Brien and Sherman 1993a). An indirect method for evaluating Ig absorption by measurement of serum gamma glutamyl transferase

310 Goat Medicine

(GGT) levels in kid serum has been reported. The mean serum GGT levels in pre-suckling newborn kids was 19 U/l, with a maximum recorded measurement of 28 U/l. At twenty-four hours after colostrum ingestion, serum GGT levels were on average six and a half times greater than pre-suckle levels, with a mean of 127 U/l and a minimum reported value of 43 U/l. The mean GGT level fell rapidly after twenty-four hours, so timing appeared critical in the evaluation of the test results (Braun et al. 1984). Goats with septicemia secondary to failure of passive transfer are likely to be severely leukopenic and may show hyperfibrinogenemia. Necropsy results are nonspecific, but bacterial culture results of heart blood and various other organs can establish the presence of septicemia. Diagnosis Decreased serum Ig levels in newborn kids twentyfour hours of age or older confirms the presence of FPT. The contribution of this condition to concurrent disease problems can only be inferred. In kids dead before twenty-four hours, FPT may be contributory, but this is more difficult to establish. Hypothermia and hypoglycemia must always be considered in the differential diagnosis of septicemia secondary to FPT. Hypoglycemia may be presumed in the live animal by measurement of blood glucose, although blood glucose is also likely to be decreased in active septicemia. The absence of an inflammatory hemogram supports primary hypoglycemia, as does the absence of a milk clot in the abomasum or ingesta in the small intestine, indicating lack of feed intake. A diagnosis of hypothermia is supported by low body temperature in conjunction with environmental conditions that would promote chilling such as outdoor kidding, cold temperatures, wet weather, and drafts. In individual kids, congenital abnormalities must also be considered as a cause of early death. Under conditions of extremely poor management and with sufficiently virulent organisms, septicemias can occur even when adequate colostrum has been ingested shortly after birth. Treatment In most cases, FPT first comes to the veterinarian’s attention because of a primary complaint of early deaths or signs of shock suggesting the presence of septicemia. Immediate attention must be given to the management of the infection. Animals should be moved to a warm, dry environment. Intravenous fluid therapy including glucose and sodium bicarbonate should be initiated to counter the hypoglycemia and circulatory effects associated with septic shock. Parenteral nonsteroidal anti-inflammatory drugs such as flunixin meglumine may be helpful. Antibiotic therapy is essential. Choice of drugs ideally should depend on

blood culture, but therapy should be initiated immediately with broad spectrum antibiotics, especially those with efficacy against Gram-negative species. Trimethoprim-sulfa combinations or gentamicin combined with ampicillin can be effective. Aminoglycoside drugs must be used cautiously to avoid serious renal damage, particularly if fluid therapy is not used concurrently. Chloramphenicol, where permitted, is also effective in septicemia. Correction of the hypogammaglobulinemia requires transfusion of plasma or whole blood. The volume required to replace the Ig deficit depends on the known level of circulating Ig in the sick kid and the average or known level of Ig in the blood of the donor goat. The average circulating serum Ig level of does is approximately 20 mg/ml. Although the minimum level of acceptable circulating immunoglobulin required by the kid has not been established, in most cases an initial transfusion of at least 250 ml of plasma is required for an average-sized kid. Repeated evaluation of zinc sulfate turbidity test results after plasma administration can aid in determining the need for additional transfusions. Prevention All goat caretakers should be aware of the potential economic losses associated with failure of passive transfer of antibody to newborn kids and educated on aspects of neonatal management related to colostrum administration. Careful observation of goats at kidding time may be necessary to identify individual kids that do not effectively suckle by six hours of age. These kids should be bottle fed or tubed with colostrum at a rate of 50 ml of colostrum per kg bw for each of three feedings over the first twelve to twenty-four hours of life. In intensive management systems, caretakers responsible for kid rearing can be encouraged to electively administer colostrum to all kids routinely within six hours of birth rather than wait for it to occur naturally. The maintenance of a frozen colostrum bank ensures that all kids have colostrum available regardless of the status of their dams. In preparing frozen colostrum, only that taken from does during the first twelve hours after kidding should be kept for freezing, because the concentration of Ig in colostrum falls off rapidly and dramatically after the first stripping. It is reported that Ig concentration of caprine colostrum shows a strong positive correlation to its specific gravity, so that colostrum quality can be screened using a colostrometer. Colostrum with a specific gravity more than 1.029 is preferred (Ubertalle et al. 1987). Bovine colostrum, either fresh or frozen, has been used successfully as a substitute for ewe colostrum in rearing lambs. This has also gained popularity in goat rearing in an attempt to limit the colostral transmission of CAE virus in kids.

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Serum antibody levels achieved in kids suckling bovine colostrum are equivalent to those obtained with caprine colostrum (Sherman et al. 1990). However, this practice must be viewed with caution; in France, a hemolytic syndrome has been reported in some kids at one week of age after consumption of bovine colostrum. It was demonstrated in vitro that bovine antibodies were directed against some caprine erythrocytes (Perrin et al. 1988). Concerns have arisen regarding the impact of heat treatment techniques on immunoglobulin content of goat colostrum used in caprine arthritis encephalitis (CAE) control programs. The original heat treatment protocol of 56°C (132.8°F) for sixty minutes was developed to avoid the denaturing effect on antibody associated with the higher temperatures of pasteurization, while still inactivating the CAE virus (Adams et al. 1983). However, more recent studies demonstrate in vitro that heat treatment of colostrum at 56°C for sixty minutes reduces measurable IgG in colostrum by approximately 37% (Argüello et al. 2002). Nevertheless, if the initial concentrations of the colostrum that is heat treated are sufficiently high, successful passive transfer of antibody may still be achieved. In recent years, a number of commercial products have become available that have been promoted as colostrum supplements for calves, lambs, and kids but have been used by goat owners as colostrum substitutes in part to avoid the need for heat treating colostrum for CAE control, which can be cumbersome and time consuming. These products are usually in the form of soluble powders or boluses. In one study, two of these products were evaluated in kids. There was virtually no detectable increase in circulating serum Ig levels in colostrum-deprived kids receiving these oral products within twelve hours of birth. Therefore, the value of these products as sources of protective Ig must be viewed skeptically (Sherman et al. 1990). Other reports have corroborated the inadequacy of certain colostrum substitutes in achieving adequate immunoglobulin levels in kids receiving the products (Constant et al. 1994).

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reaction in goats (LD typing). Vet. Immunol. Immunopathol. 2:321–330, 1981. Van den Ingh, T.S.G.A.M., et al.: The pathology and pathogenesis of Trypanosoma vivax infection in the goat. Res. Vet Sci., 21:264–270, 1976. Van der Hoeden, J.: Leptospirosis among goats in Israel. J. Comp. Pathol., 63:101–111, 1953. Van Miert, A.S.J.P.A.M., Van Duin, C.T.M., Schotman, A.J.H. and Franssen, F.F.: Clinical, haematological and blood biochemical changes in goats after experimental infection with tick-borne fever. Vet. Parasitol., 16:225–233, 1984. Van Miert, A.S.J.P.A.M., Van Duin, C.T.M. and Wensing, T.: The effects of ACTH, prednisolone and Escherichia coli endotoxin on some clinical hematological and blood biochemical parameters in dwarf goats. Vet. Q. 8:195–203, 1986. Veenendaal, G.H., et al.: A comparison of the role of kinins and serotonin in endotoxin induced fever and Trypanosoma vivax infections in the goat. Res. Vet. Sci., 21:271–279, 1976. Verheijden, J.H.M., van Miert, A.S.J.P.A.M. and Van Duin, C.T.M.: Demonstration of circulating endogenous pyrogens in Escherichia coli endotoxin-induced mastitis. Zentralbl. Veterinaermed. A, 30:342–347, 1983. Vihan, V.S. and Sahni, K.L.: Role of blood gammaglobulin in relation to the neonatal kid mortality and their subsequent performance. Proc. III International Conf. Goat Prod. Dis., Tuscon, Arizona, pp. 372, 1982. Vihan, V.S.: Glutaraldehyde coagulation test for detection of hypogammaglobulinaemia in neonatal kids. Indian Vet. J., 66:101–105, 1989. Wasfi, I.A. and Adam, S.E.I.: The effects of intravenous injection of small amounts of copper sulphate in Nubian goats. J. Comp. Pathol., 86:387–391, 1976. Weber, W.T.: Evaluation of bone marrow. In: Textbook of Veterinary Clinical Pathology, W. Medway, J.E. Prier, and J.S. Wilkinson, eds. Baltimore, Williams and Wilkins Co., 1969. Webster, K.A. and Mitchell, G.B.B.: Use of counter immunoelectrophoresis in detection of antibodies to tick-borne fever. Res. Vet. Sci., 45:28–30, 1988. Whitelaw, D.D., et al: Susceptibility of different breeds of goats in Kenya to experimental infection with Trypanosoma congolense. Trop. Anim. Health Prod. 17:155–165, 1985. Whitelaw, D.D., Moulton, J.E., Morrison, W.I. and Murray, M.: Central nervous system involvement in goats undergoing primary infections with Trypanosoma brucei and relapse infections after chemotherapy. Parasitology, 90:255–268, 1985a. Whitford, H.W.: Anthrax in dairy goats. Southwest. Vet., 35:15, 1982. Wilkins, J.H. and Hodges, R.R.D.H.: Observations on normal goat blood. J. R. Army Vet. Corps, 33:7–10, 1962. Yin, H., et al.: Phylogenetic analysis of Theileria species transmitted by Haemaphysalis qinghaiensis. Parasitol. Res., 92:36– 42, 2004. Yousif, Y.A., Dimitri, R.A., Dwivedi, S.K. and Ahmed, N.J.: Anaemia due to anaplasmosis in Iraqi goats: I. Clinical and haematological features under field conditions. Indian Vet. J., 60:576–578, 1983.

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8 Cardiovascular System Background Information of Clinical Importance 319 Anatomy and Physiology 319 Diagnostic Methods 320 Diagnosis of Cardiovascular Disease by Presenting Sign 323 Sudden Death 323 Abnormal Heart Sounds 325

The occurrence of clinically recognized cardiovascular disease in goats is very low. As a result, goats have been the least studied of the domestic species regarding normal cardiovascular function and pathophysiology. In recent years, however, goats have received more attention as a suitable animal model for the study of human cardiovascular disease and its management. In particular, goats have been used in studies of the pathophysiology and treatment of atrial fibrillation (Neuberger et al. 2006), chronic heart failure (Tessier et al. 2003), the development of skeletal muscle ventricles (Guldner et al. 2002), the development and testing of artificial heart valves (Björk and Kaminsky 1992), and the use of total artificial hearts (Abe et al. 2007). As reported in 2007, the world record for survival of an animal with a total artificial heart belongs to a goat outfitted with a paracorporeal total artificial heart that survived for 532 days (Abe et al. 2007).

BACKGROUND INFORMATION OF CLINICAL IMPORTANCE Anatomy and Physiology Structure of the Heart and Vessels The heart of the goat extends from the third to the sixth rib and may contact the diaphragm at its caudal edge. The position and orientation within the thorax is similar to that of other ruminants. The adult heart may contain two small cardiac bones, the right and left os cordis located around the aortic ring (Aretz 1981). However, a more recent study reported that in a series of fifty goats examined, only a right os cordis was Goat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Arrhythmias 326 Congestive Heart Failure 326 Subclinical Cardiovascular Conditions 327 Specific Diseases of the Cardiovascular System 327 Heartwater 327 Schistosomosis 330 References 334

present, located beneath the septal cusp of the tricuspid valve near the junction of the interatrial and interventricular septae and that it was only present in 44% of the hearts examined (Mohammadpour and Arabi, 2007). Purkinje fibers extend deep into the myocardium of the goat heart, as in other ruminants, which has clinical implications regarding the diagnostic value of electrocardiography as discussed later in this chapter. Anomalies of the heart reported in goats include ventricular septal defects (VSD) in the lower, middle, and upper ventricular septum (Parry et al. 1982), and ectopia cordis, with the heart exposed to the outside through a fissured sternum (Narasimha Rao et al. 1980). Kids with ectopia cordis may be born alive and survive for hours or days (Upadhye and Dhoot 2001) or they may be born dead with structural abnormalities of the externalized heart such as a single ventricle (Dadich 2000). There are no major differences in the structure and distribution of the great vessels of goats compared with other ruminants. Anomalies of the great vessels are uncommon, but persistence of the left cranial vena cava (Waibl 1973), dextroposition of the aorta (Parry et al. 1982), and aortic stenosis (Scarratt et al. 1984) have been reported. Parameters of Blood Flow Information on cardiac output, stroke volume, systolic and diastolic arterial pressures, pulmonary arterial pressure, pulmonary arterial flow rates, and central venous pressure has been published, but the numbers of animals involved in the various studies have been 319

320 Goat Medicine

limited (Jha et al. 1961; Hoversland et al. 1965; Foex and Prys-Roberts 1972; Ivankovich et al. 1974; Vesal and Karimi 2006). Mean cardiac outputs in goats of various breeds, age, and sex have been reported in the range of 2.8 ± 0.7 l/minute to 4.8 ± 1.4 l/minute (Hoversland et al. 1965; Foex and Prys-Roberts 1972; Ivankovich et al. 1974; Olsson et al. 2001). More recently, significant differences in cardiac output were confirmed in dairy goats during pregnancy (6.73 ± 0.72) as compared to lactation (6.12 ± 0.52) and the dry period (4.39 ± 0.27) in the same individuals (Olsson et al. 2001). Mean stroke volumes derived from a measurement of cardiac output and heart rate or measured directly by dye dilution technique have been reported in the range of 20.3 ± 3.1 ml to 46.9 ± 23 ml (Foex and PrysRoberts 1972; Ivankovich et al. 1974). Mean systolic arterial pressure recorded from goats of varying breeds, age, and sex ranged from 122 to 124.9 mm Hg, while mean diastolic pressures in the same goats ranged from 85 to 97.8 mm Hg (Jha et al. 1961; Hoversland et al. 1965). Mean central venous pressure in goats of both sexes was reported as 1.25 ± 0.14 cm H2O but there was a statistically significant difference between males (0.80 ± 0.11) and females (1.9 ± 0.26). There was no difference noted, however, between standing goats and those in lateral recumbency (Vesal and Karimi 2006). Normal Heart Rate and Rhythm The heart is heard most audibly over the left thoracic wall at the fourth intercostal space. Heart rate varies considerably in goats with age and level of activity. Mean heart rates for small numbers of goats at different ages have been reported from India (Upadhyay and Sud 1977). Barbari goat kids from birth to fifteen days of age had mean heart rates of 255 ± 15 bpm, and 209 ± 6 bpm from sixteen days to one month of age. By one to six months of age, mean heart rates had decreased to 142 ± 6 bpm and to 125 ± 9 bpm between six and twelve months. Goats one to three years of age had heart rates of 126 ± 5 bpm, and goats three to five years of age, 126 ± 7 bpm. In one American study of one hundred male goats one to one and a half years of age, the mean heart rate was 96 bpm with a range of 70 to 120 (Szabuniewicz and Clark 1967). In a second American study of eight adult females of mixed breed, the mean was 105 bpm with a range of 90 to 150 (Jha et al. 1961). While it is generally presumed that fear and distress increase the heart rate in goats, a study involving goat responses to unfamiliar human contact could not demonstrate a significant elevation in heart rate (Lyons and Price 1987). Using telemetric recording of heart rate, investigators demonstrated a significant increase in heart rate of

normal young goats during physical examination (116 ± 11.7 bpm) compared with before (92.2 ± 6.3 bpm) and a significantly higher rate when eating (114.1 ± 2.1 bpm) as compared to standing (84.2 ± 0.9 bpm) or lying down (76.5 ± 1.1 bpm) (Vesal et al. 2000). Other investigators have reported significant differences in heart rates in goats of different breeds kept under similar conditions (Medeiros et al. 2001) and elevated heart rates in pregnant does as compared to the same does when lactating and when non-pregnant and non-lactating (Olsson et al. 2001) Two heart sounds are normally heard in the goat, S1 and S2. A normal respiratory sinus arrhythmia is common, with acceleration occurring in late inspiration. It is more pronounced in younger goats. Second degree A-V block, though uncommon, has been recorded in a normal goat (Szabuniewicz and Clark 1967). Diagnostic Methods Electrocardiography The electrocardiogram (ECG) has been applied relatively infrequently in caprine medicine. Nevertheless, some parameters for the ECG tests in normal goats have been established using standard and augmented limb leads (Szabuniewicz and Clark 1967; Upadhyay and Sud 1977). The goat may be evaluated while standing or in left or right lateral recumbency with little effect on the ECG. Limb leads should be placed on the anteriolateral aspect just above the elbow joint in the forelimb, and just above the stifle joint in the hind limb. Electrocardiography has also been performed with the leads in a sagittal plane between the ears, on the sacrum, and on the sternum (Schultz and Pretorius 1972). Interval durations, in seconds, have been reported for the P-wave, P-R interval, QRS complex, Q-T interval, and T-wave (Jha et al. 1961; Szabuniewicz and Clark 1967; Schultz and Pretorius 1972; Upadhyay and Sud 1977; Ogburn et al. 1977). Minimal differences occur between various leads (Szabuniewicz and Clark 1967). The amplitudes of ECG deflections are small in the goat. Mean amplitudes for various leads as measured in one hundred goats have been reported (Szabuniewicz and Clark 1967). Duration and amplitude measurements reported for the commonly used lead II are given in Table 8.1. The P-wave is most often peaked in standard and augmented leads, but is occasionally flat or rounded. Biphasic P-waves are rarely seen. The P-wave is usually positive in the standard leads and the augmented leads, except for aVR. Changes in the shape of P-waves may be observed sometimes in normal goats, representing wandering of the pacemaker in the sinoatrial node.

8/Cardiovascular System 321 Table 8.1. Electrocardiographic parameters for lead II reported in normal goats. Parameter

P-wave amplitude (mv)

P-wave duration (sec)

P-R interval duration (sec)

QRS complex amplitude (mv)

QRS complex duration (sec)

Q-T interval duration (sec)

T-wave amplitude (mv)

T-Wave duration (sec)

Mean values Range

0.080 0.02–0.15

0.04 0.02–0.06

0.09–0.13 0.06–0.16

0.258 0.10–0.70

0.039–0.045 0.03–0.08

0.295–0.334 0.22–0.38

0.200 0.05–0.50

0.07 0.04–0.10

QRS = principal deflection in an electrocardiogram.

The shape of the QRS complex is quite variable within and between the different leads. It is usually mono- or diphasic and infrequently triphasic. In lead I, a QS pattern dominates. In lead II, QS or Qr patterns are most often recorded. In lead III, no single pattern is predominant, and the Qr, qR, R, RS, and Rs patterns commonly occur. Q waves are rarely observed in the aVR lead, and the R and Rs patterns predominate. In the aVL lead, the QS pattern is most common, followed in frequency by the rS pattern. In lead aVF, either the Qr or the QS patterns may predominate, with the R, RS, Rs, and rS patterns also common. Because of the variability of the QRS complex in particular, it is generally considered that there is no typical morphologic pattern that is characteristic for the ECG test results of the goat using the common lead systems. The T-wave occurs most commonly in the peaked form. Flat, round, or diphasic T-waves are uncommon. In most cases, the T-wave is of opposite polarity or deflection to the accompanying QRS deflection, although concurrent positive deflections occur in lead III and concurrent negative deflections in lead aVL. Vectorcardiography is of limited clinical value in goats. As is the case with other ruminants, Purkinje fibers fully penetrate the ventricular wall with extensive ramification. This permits rapid excitation of both ventricles, resulting in near cancellation of potentials within the wall. As a result, subtle changes in vector orientation or QRS wave structure resulting from cardiac derangements are difficult to distinguish. The occurrence of rapid, simultaneous activation of both ventricles in a period of approximately 10 milliseconds has been well documented in the goat. The pattern of depolarization observed is virtually identical to that of the calf (Hamlin and Scher 1961). In an experimental model of right ventricular hypertrophy, no significant alteration of the QRS complex or vector orientation was identifiable in affected goats. The Q-T interval shortened in goats with right ventricular hypertrophy, but this was attributed to the increased heart rate that occurred (Ogburn et al. 1977). Nevertheless, detailed studies of three goats with naturally occurring ventricular septal defects indicate that prolongation of P-R intervals and P-, QRS, and T-wave intervals and

amplitudes may suggest cardiac enlargement (Parry et al. 1982). Radiography The radiographic anatomy of the caprine thorax has been described (Singh et al. 1983). In dorsoventral radiographs, the normal heart lies between the second or third intercostal space and the sixth or seventh space, with the base centered over the midline and the apex shifted to the left of midline. While not universally accepted, measurement of contact area of the heart with the sternum has been used to evaluate cardiac enlargement secondary to ventricular septal defect in the goat. Normal hearts had a mean contact area of 3.3 sternebrae; abnormal hearts had a mean contact area of 6 (Parry et al. 1982). Echocardiography While M-mode, two dimensional (B-mode), and Doppler echocardiography are being applied more frequently to the diagnosis of suspected heart disease in goats, published information on normal echocardiographic parameters in the goat remains limited. In one study, mitral, aortic, and tricuspid valves were identified at the right third and fourth intercostal spaces slightly dorsal to the olecranon. The pulmonic valve was identified at the same location on the left (Yamaga and Too 1984). In a more recent study, technical difficulties were noted with regard to echocardiographic examination of the goat. The cranial location of the heart partly covered by the olecranon and the caudal brachial muscles, along with the narrow intercostal spaces, made it difficult to position the ultrasound transducer and limited the acoustic window (Olsson et al. 2001). Nevertheless, echocardiographic and Doppler measurements were obtained in eight normal Swedish domestic goats during pregnancy, lactation, and the dry period. These measurements are presented in Table 8.2. A separate study of eight normal goats in the Philippines also reports normal caprine cardiac parameters measured by B-mode and M-mode ultrasonography (Acorda et al. 2005).

322 Goat Medicine Table 8.2. Echocardiographic and Doppler measurements and calculated stroke volume and cardiac output during pregnancy, lactation, and dry period in the same eight goats (Capra hircus). Reproductive periods Measurements

Pregnancy −1

HR (M-mode; beats min ) AO (mm) LA (mm) LVEDD (mm) LVESD (mm) LVWd (mm) LVWs (mm) FS (%) HR (Doppler; beats min−1) VTI (cm s−1) Vmax (m s−1) Stroke volume (ml) Cardiac output (l min−1)

148 ± 4*** 23.9 ± 0.7 26.2 ± 1.0 39.6 ± 1.5 23.4 ± 1.4 6.9 ± 0.4 12.8 ± 0.5 41.1 ± 2.0 133 ± 3** 10.5 ± 1.1 1.0 ± 0.0 47 ± 5 6.73 ± 0.72** †

Lactation

Dry period

123 ± 5 23.9 ± 0.4 27.9 ± 0.6 40.5 ± 1.0 23.8 ± 0.5 6.5 ± 0.3 12.3 ± 0.6 41.1 ± 1.1 114 ± 4 11.5 ± 0.8 1.1 ± 0.0 54 ± 5 6.12 ± 0.52

107 ± 9 24.3 ± 0.6 26.9 ± 0.3 40.6 ± 1.0 24.0 ± 0.8 6.8 ± 0.3 12.9 ± 0.6 40.6 ± 1.2 100 ± 6 9.5 ± 0.4 0.9 ± 0.0 45 ± 3 4.39 ± 0.27†

HR = heart rate; AO = aortic root; LA = left atrium; LVEDD and LVESD = left ventricular enddiastolic and end-systolic diameter, respectively; LVWd and LVWs = left ventricular wall thickness in diastole and systole, respectively; FS = fractional shortening of the left ventricle; VTI = velocity trace integral; Vmax = maximal aortic flow. Values are means ± S.E.M. ** P < 0.01 and *** P < 0.001 vs. dry period; † P < 0.05 vs. lactation. (From Olsson, K., et al., A serial study of heart function during pregnancy, lactation and the dry period in dairy goats using echocardiography. Experim. Physiol., 86(1):93–99, 2001. Used with permission of Wiley-Blackewll Publishing.)

There is one published case report on the use of echocardiography for the diagnosis of heart disease in a goat (Gardner et al. 1992). In that report, a three-yearold pygmy buck was evaluated for a systolic murmur. Echocardiography revealed an enlarged right atrium and ventricle, an atrial septal defect, and a dysplastic tricuspid valve, while color-flow Doppler echocardiography revealed severe tricuspid regurgitation and a right to left shunt through the atrial septal defect. A diagnosis of Ebstein’s anomaly of the tricuspid valve was made, the first such report in goats. Ultrasonography has also been used to identify cardiac and pulmonic abnormalities associated with enzootic calcinosis in goats (Gufler et al. 1999) Pericardiocentesis Indications for pericardiocentesis in the goat are limited. Traumatic reticuloperitonitis, which is a well known condition in cattle, is rarely reported in goats in the veterinary literature. Pericardial effusions may occur in caprine heartwater (cowdriosis), but the fluid is not useful for diagnostic purposes. Pericarditis also occurs in conjunction with systemic mycoplasmosis but the organism is more easily isolated from other sites. If attempted, pericardiocentesis is best performed at the right fourth intercostal space low on the chest

wall to avoid lung and coronary arteries. The animal can be standing or in lateral recumbency. Chemical restraint such as diazepam is advisable. Surgical access to the pericardium can be accomplished by resection of the left fourth rib. Computed Tomography Computed tomography of the caprine thorax has been described (Smallwood and Healey 1982). The heart is visible in cross-section beginning at the caudal aspect of thoracic vertebra T1 and ending at the middle of T5. The right side of the heart is more visible in the anterior cross sections and the left side in the posterior sections. At the level of the caudal aspect of T2, the heart silhouette is in contact with both the right and left thoracic walls. Angiography Left ventricular angiocardiograms in goats have been reported for the diagnosis of VSD. Passage of a catheter was performed via the left and right carotid arteries to acquire angiographic and hemodynamic data (Parry et al 1982; Scarratt et al. 1984). Arteriography and ultrasonography also have been applied to studies of the carotid artery diameter and blood flow velocity in goats (Lee et al. 1990).

8/Cardiovascular System 323

Clinical Chemistry The reported use of clinical chemistry in the diagnosis of caprine heart disease is limited. Myocardial damage or necrosis can lead to release of various enzymes into the circulation, including aspartate aminotransferase (AST), lactate dehydrogenase (LDH), and creatine kinase (CK). However, skeletal muscle damage can also result in measurable increases in serum concentrations of these enzymes. In the case of LDH and CK, measurement of cardiac specific isoenzymes might confirm the involvement of heart muscle, but the cardiac specificity and reference values for caprine isoenzymes of LDH and CK are not well documented. In recent years, measurement of the myofibrillar contractile protein, troponin, in plasma has become the accepted standard biomarker for acute myocardial infarction in human patients and it is also increased in patients with decreased left ventricular function without acute myocardial infarction (Ammann et al. 2003). Reference values for measurement of troponin (cTNI) in plasma of healthy dogs have been recently published, with a median value of 0.03 ng/mL and a range of 0.01 to 0.15 ng/mL (Oyama and Sisson 2004). Goats have intermediate levels of troponin (cTNT) relative to other domestic species and it has been demonstrated that a second generation immunoassay can detect cardiac muscle troponin cTNT in blood (O’Brien et al. 1998).

DIAGNOSIS OF CARDIOVASCULAR DISEASE BY PRESENTING SIGN Heart disease is not common in goats and the world literature on caprine cardiovascular disease is sparse. One Indian study on the prevalence of gross cardiac abnormalities in slaughtered goats found approximately 3.5% of 2,720 hearts examined to be abnormal (Chattopadhyay and Sharma 1972). A slaughterhouse survey of 29,687 goats in Zimbabwe identified 525 (1.6%) instances of pericarditis (Chambers 1990). Nevertheless, in routine clinical examination, some physical findings may suggest cardiovascular disease in goats, and these findings should be pursued. The differential diagnoses for clinical signs suggesting cardiovascular disease are given below. Sudden Death Attribution of sudden death to cardiac disease must be approached cautiously in goats. The presence of gross or microscopic lesions in the heart at necropsy does not always mean that heart disease contributed to the clinical picture. Some changes may be artifactual, related to autolysis, blanching of the heart muscle during rigor mortis, or uneven staining of histologic sections (Newsholme and Coetzer 1984). In addition,

a number of abnormalities may be noted in the heart, pericardium, or great vessels that represent subclinical conditions unrelated to the cause of death. These are discussed below in the section on subclinical cardiovascular conditions. Peripheral evidence of cardiac dysfunction may be a better indicator of heart involvement than abnormalities of the heart itself. These include passive congestion, lung edema, and fluid accumulation in the thorax, pericardium, or abdomen. Histologic evaluation in all cases of the heart should be performed to identify definitive changes when present. The following cardiac causes of sudden death must be considered. Nutritional Muscular Dystrophy Nutritional muscular dystrophy or white muscle disease can affect the heart muscle and skeletal muscle and may be responsible for sudden death caused by cardiac failure, particularly in young kids. The disease is discussed in detail in Chapter 4. Cardiotoxic Plants A number of plants may cause heart failure and sudden death in goats. In North America, potentially cardiotoxic plants include the ornamental plants oleander (Nerium oleander), foxglove (Digitalis purpurea), lily of the valley (Convallaria majalis), and yew (Taxus spp.). Other weeds and shrubs include Indian hemp (Apocynum cannabinum), false hellebore (Veratrum spp.), and milkweed (Asclepias spp.) (Fowler 1986). Yew and false hellebore contain toxic alkaloids, while the other plants contain cardiac glycosides. In all cases, such poisonings would be sporadic and require careful documentation of exposure. Rumen contents should be examined for identifiable plant parts. The outcomes of these cases often depend on the level of exposure. If nonlethal doses are consumed, clinical signs may persist for several days, because the half-life of most cardiac glycosides is between twenty-four and thirtysix hours. Successful management of yew toxicity in goats has been reported. Two goats died within twenty-four hours of ingesting the ornamental shrub and three remaining goats showed signs of bradycardia, hypothermia, depression, and weakness. Rumenotomies were performed on these goats to remove ingested plants, and mineral oil, electrolytes, and activated charcoal were added to the rumen. All three survived (Casteel and Cook 1985). In South Africa, gousiekte, or “quick disease” occurs commonly enough to produce serious economic loss in livestock, including goats. It is caused by six different plants in the family Rubiaceae: Pachystigma pygmaeum, P. thamnus, P. latifolium, Pavetta schumanniana, P. harborii, and Fadogia homblei. It is a cumulative

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poisoning and usually requires several weeks of ingestion of these plants before clinical disease occurs. Goats are more susceptible than sheep (Hurter et al. 1972). The toxic principle in these plants has been isolated. It is a water soluble, heat stable, cationic polyamine that has been termed pavetamine (Fourie et al, 1995). The toxin has been shown to inhibit the synthesis of new myosin during the turnover of myocardial proteins (Schultz et al. 2004). Under range conditions, the disease is perceived as one that causes sudden death after a latent period of three to six weeks following ingestion of the offending plants. However, if animals are carefully observed, prodromal signs of lagging behind the flock, lying down with head and neck extended, dyspnea, and coughing may be noted during this latent period (Pretorius and Terblanche 1967). At necropsy, there is gross evidence of heart failure including general congestion, pulmonary edema, ascites, hydrothorax, and hydropericardium. Histologically, the most consistent finding is hypertrophy of myocardial fibers in the subendocardial region (Prozesky et al. 2005). Other South African plants that can result in sudden death include Cotyledon orbiculata and Dichapetalum cymosum. The succulent plant C. orbiculata contains bufadeniolides, which are cardiac glycosides. When large amounts of the plant are consumed by goats over a short period of time, sudden death from heart failure can occur (Tustin et al. 1984). This may be preceded by signs of weakness, prostration, tachycardia, and pupillary constriction. The toxic principle in D. cymosum, a plant known as gifblaar, is monofluoroacetic acid. Death occurs within a few hours of ingestion. Peritoneal, pericardial, and thoracic effusions may be observed at necropsy, and histological examination of the heart may demonstrate multiple small foci of myocardial necrosis, with lymphocytic infiltration. However, these are not consistent findings (Newsholme and Coetzer 1984). A related species, D. barteri, has been identified as a cause of sudden death in goats eating branches of the tree in Nigeria (Adaudi 1975; Nwude et al. 1977). Sudden death in South African goats has also been reported three days after ingestion of avocado leaves (Persea americana), presumably because of heart failure (Grant et al. 1988). The cardiotoxicity of avocado leaves has since been confirmed experimentally in two goats (Sani et al. 1991). One died suddenly without showing clinical signs while the second developed muffled heart sounds, tachycardia, and tachypnea before dying two days after challenge. At necropsy, there was pleural and pericardial effusion, pulmonary edema, ascites, hepatic congestion, and a pale, flabby heart with widespread degeneration of myocardial fibers seen microscopically. Avocado, oleander, caltrops (Calotropis procera), and red cotton (Asclepias curassavica) have

also been reported as causes of cardiotoxicity in goats in Australia (Seawright 1984). In the Sudan, a commonly grazed annual shrub, Cassia occidentalis, has been demonstrated to produce a toxic myodegeneration of cardiac muscle in goats (Suliman and Shommein 1986). C. occidentalis is also found in the southwestern United States and is known as coffee weed, senna, or coffee senna. It has been associated with death in grazing cattle because of skeletal and cardiac myodegeneration, so goats must be considered at risk. In all cases of sudden death, when plant toxicity is suspected, additional animals at risk should be removed from the potential source and given activated charcoal orally at a minimum dose of 2 g/kg bw. Heartwater Heartwater (cowdriosis), discussed in detail later in this chapter, occurs principally in Africa as well as in some Caribbean islands and can cause peracute death in goats. Lesions observed after death are similar to those described for gousiekte. Where both diseases occur, they must be differentiated by examination of brain tissue for the presence of the rickettsial organisms that cause heartwater. Foot and Mouth Disease Foot and mouth disease (FMD) is usually a subclinical infection in goats or it produces mild to moderate signs of lameness in adults. However, very young kids in infected herds may die suddenly of associated viral, lympho-histiocytic myocarditis which can produce a gross lesion of either diffuse gray spots or more organized “tiger” stripes, mainly in the left ventricle and interventricular septum (Kitching and Hughes 2002). FMD is discussed in more detail in Chapter 4. Other Cardiotoxic Agents Iatrogenic cardiotoxicity is possible in goats because of overdosage with at least two commonly used substances, calcium salts and ionophore coccidiostats. However, confirmation of sudden death in goats because of these substances is lacking. When treating milk fever (hypocalcemia), it is always advisable to administer intravenous calcium slowly and monitor the heart sounds for arrhythmia, increased rate, or heart block. Goats that are below average weight, have concurrent diseases, or have already been treated by the owner are more likely to experience cardiac irregularities or arrest. Ionophore toxicity is known to occur in small ruminants. Ionophore antibiotics are used in livestock production as coccidiostats for cattle, sheep, goats, and poultry and the ionophore monensin is also used as a growth promotant that improves feed efficiency and weight gain in beef cattle. Monensin has caused

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sudden death in sheep fed three or more times the recommended dose of 15 to 22 ppm. The affected sheep readily consumed feed containing this amount, contrary to the general assumption that feed refusal occurs when the level is more than twice the recommended dose. Sudden death occurred in 20% to 40% of affected sheep and microscopic cardiac lesions ranging from focal necrosis with perivascular lymphocytic cuffing to necrotizing myocarditis were present (Bastianello 1988). Monensin is approved for oral use in confined goats in the United States as a coccidiostat at a dose of 20 g/ ton of feed (22 ppm). Goats experimentally given monensin orally at the rate of 55 ppm in feed for three weeks showed anorexia, diarrhea, and an increase in serum sorbitol dehydrogenase, indicating some hepatotoxicity (Dalvi and Sawant 1990). There are no published reports of field cases of monensin toxicity in goats but experimental data indicate that the single dose oral LD50 for monensin in goats is 26.4 mg/kg bw (12 mg/lb)(Beasley 1999). There is however, a report of fatal overdose of goats with the ionophore salinomycin. Angora goats in Turkey were fed salinomycin in their ration at a rate of 680 ppm/kg of feed due to a mechanical mixing malfunction during feed preparation. Thirteen of 70 exposed goats died. Among those for which there was an opportunity for clinical examination before death, signs included listlessness, inappetence, incoordination, dehydration, fluid stool, tachycardia, muscle weakness, salivation, panting, and prostration, and death occurring within fifteen to twenty-four hours. At necropsy there was excessive fluid in the abdomen, thorax, and pericardium. The heart showed petechiation in the ventricles and endocardium and microscopically there was prominent myocardial hemorrhage (Agaoglu et al. 2002). The recommended dose of salinomycin for use in goats as a coccidiostat is 100 ppm of concentrate fed. Sudden death also has been reported in goats fed excessive amounts of vitamin D. At necropsy, calcification of the coronary arteries and aorta were noted (Neumann et al. 1973). Trauma It has been suggested that goats, due to their generally low pain threshold, can die of cardiac failure resulting from neurogenic or catecholamine-induced ventricular dysrhythmias when subjected to painful procedures such as dehorning without appropriate analgesia or anesthesia (Gray and McDonell 1986). Aortic Rupture In tropical regions, nematode infections of the aorta with Spirocerca lupi and/or Onchocerca armillata have been reported in goats (Chowdhury and Chakraborty

1973). These infections may be subclinical or identified at necropsy or slaughter by thickening, nodularity, or calcification of the aorta. However, S. lupi in the goat aorta can lead to slow bleeding with anemia and emaciation or to aortic rupture and sudden death (Chhabra and Singh 1972). Neoplasia There is one reported case of a three-year-old pregnant female goat that died suddenly when being chased around its pen to be medicated for undiagnosed chronic respiratory disease of about one month duration. On necropsy the goat had ovine pulmonary adenomatosis (jaagsiekte) with tumor in both lungs that had also metastasized to the kidneys and heart. Death was attributed to heart failure secondary to tumor infiltration of the myocardium of the left ventricle (Al-Dubaib 2005). Jaagsiekte is uncommon in goats and is discussed further in Chapter 9. Abnormal Heart Sounds Documentation of abnormal heart sounds in goats is limited. Murmurs In cases of VSD, grade IV or V out of VI holosystolic murmurs over both the right and left heart base with palpable thrills on both sides have been reported (Scarratt et al. 1984). An audible S4 sound was heard to precede S1 in one case of VSD (Parry et al. 1982). Systolic murmurs can be heard during the prodromal phase of gousiekte (Pretorius and Terblanche 1967). Reports of abnormal heart sounds associated with valvular abnormalities are rare. A single case of endocarditis has been reported in a Pygmy goat that presented clinically with a continuous rasping cardiac murmur, increased heart rate, dyspnea, inappetence, fever, and depression. It was determined after death to have traumatic peri- and endocarditis because of heart penetration with a sewing needle (Waldman and Woicke 1984). Two additional cases of vegetative endocarditis in goats have been identified only as incidental post mortem findings (Geisel 1973; Krishna et al. 1976). A grade III/V plateau pansystolic murmur was auscultated over the tricuspid valve area and a grade II/V plateau pansystolic murmur was auscultated over the left heart base in a three-year-old male pygmy goat with Ebstein’s anomaly of the tricuspid valve (Gardner et al. 1992). Systolic murmurs of variable character have been reported in cases of enzootic calcinosis in goats in Austria (Gufler et al. 1999) and Switzerland (Braun et al. 2000) in association with the consumption of golden oat grass (Trisetum flavescens). Enzootic calcinosis is known to occur in ruminants and horses in various countries around the world where animals consume plants with high concentrations of 1,25

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dihdroxycholecalciferol (calcitrol) glycoside or substances that mimic its action. Chronic consumption of such plants leads to excessive absorption of calcium and results in calcification of soft tissues, primarily the cardiovascular system, but also lungs, kidneys, and tendons. Affected goats show loss of appetite, emaciation, dyspnea, and abnormalities of carriage and gait, including increased recumbency, difficulty rising, kneeling after rising, stilted gait, arched back, shifting weight from leg to leg, and intermittently carrying a limb off the ground. These locomotor signs are associated with calcification of the flexor tendons and blood vessels of the limbs. Calcification of cardiac structures including the heart valves and the great vessels also occurs in enzootic calcinosis. As a result, physical examination and ancillary diagnostic testing may reveal tachycardia, a variety of murmurs, possible arrhythmias, pericardial effusions, pleural effusions, ascites, and abnormalities in the ECG and echocardiogram, including evidence of pericarditis, thickening of the aortic orifice, and calcification of the heart valves. Calcification of the aorta is especially remarkable and may be noted in plain radiographs. There is no treatment for enzootic calcinosis, but the condition can be controlled by eliminating or reducing access to the offending plants in the ration. The calcinogenicity of yellow oat grass is reduced if it is made into hay when mature rather than grazed as fresh young grass. Muffled Sounds The principle cause of muffled heart sounds in the goat is hydropericardium resulting from the appropriately named disease heartwater, or cowdriosis. In addition, some of the African poisonous plants cited above may produce pericardial effusions. Lymphosarcoma and traumatic reticulopericarditis, the two most common causes of pericardial effusion in cattle, are rare in goats (Sharma and Ranka 1978; Waldman and Woicke 1984; Craig et al. 1986; Reddi and Surendran 1988). In one reported case of thymoma, the heart was heard over an increased area of the left thorax, and the palpable cardiac impulse was displaced dorsally by the thoracic mass (Rostkowski et al. 1985). Friction Rubs Infectious pericarditis, the most likely cause of friction rubs synchronous with the heartbeat, is infrequently reported in goats (Chattopadhyay and Sharma 1972; Hein and Cargill 1981). When it does occur, it is most often associated with general mycoplasmal infections. The pericarditis is often an extension of the pleuropneumonia commonly associated with mycoplasmal infections, notably M. mycoides subspecies mycoides and M. ovipneumoniae (Masiga and Rurangirwa 1979; East et al. 1983; Rodriguez et al. 1995; Williamson et al.

2007). Friction rubs may be heard either in association with the heartbeat or respiration or both. Exudative pericarditis can also occur in caprine tuberculosis (Savey 1984). Arrhythmias Arrhythmias are infrequently documented. They have been reported in association with the cardiac form of tuberculosis, in cardiotoxicity resulting from cardiac glycoside-containing plants, and in a case of enzootic calcinosis. Atrial fibrillation has been reported with congestive heart failure and pneumonia (Gay and Richards 1983). Gallop rhythms, tachycardia, splitting of the first heart sound, and arrhythmias occur during the prodromal phase of gousiekte (Pretorius and Terblanche 1967). Congestive Heart Failure The clinical signs of congestive heart failure are similar to those seen in other species. They include increased jugular pulse, jugular distension, moist cough, tachycardia, submandibular edema, ascites, exercise intolerance, chronic weight loss, and possibly diarrhea. Not all signs are seen in all cases. Findings in dead goats that are consistent with heart failure include hydrothorax, hydropericardium, hydroperitoneum, pulmonary edema, heart enlargement, and ventricular dilation. Congestive heart failure in the goat has been attributed to cor pulmonale secondary to pneumonia (Gay and Richards 1983), mediastinal thymoma (Rostkowski et al. 1985), and VSD (Parry et al. 1982). Krimpsiekte and gousiekte, usually recognized as sudden death, may show evidence of congestive heart failure at necropsy. Waterpens, another poisonous plant disease of goats and sheep in South Africa caused by Galenia africana, produces a marked abdominal ascites and death (van der Lugt et al. 1988). The intoxication results in both hepatic and cardiac lesions. Experimental challenge studies with plant extracts indicate that G. africana is primarily hepatotoxic with myocardial involvement occurring only in the terminal stages of the intoxication (van der Lugt et al. 1992). Nutritional muscular dystrophy (white muscle disease) may lead to congestive heart failure when heart muscle damage is not severe enough to produce sudden death. The differential diagnosis for goats with signs suggesting congestive heart failure should include gastrointestinal helminthiasis and liver fluke disease. These parasitisms can produce edema, ascites, and exercise intolerance secondary to hypoproteinemia and anemia. Marked jugular distension commonly occurs in goats whose neck chains or collars have been fastened too tightly. This should be differentiated from heart disease. Reports on therapy for congestive heart failure in goats are limited (Gay and Richards 1983). The

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principles of therapy and the drugs commonly reported in the dog can be used reasonably as a first approximation in goats. These include reduction of preload with furosemide or other diuretics; reduction of afterload with captopril, hydralazine, or other vasodilators; improvement of contractility with digoxin or dobutamine; and restoration of rate and rhythm with lidocaine, quinidine, procainamide, or other appropriate antiarrhythmic drugs (Kittleson 1985; Wilcke 1985).

SUBCLINICAL CARDIOVASCULAR CONDITIONS Lesions involving the heart and vasculature are sometimes observed at necropsy in goats when no signs of heart disease have been recognized during the clinical examination. This occurs when other clinical signs overshadow cardiovascular disease, when cardiovascular disease is subclinical, or when lesions observed are non-pathogenic. Pericardial effusions or pericarditis may be seen in mycoplasmosis, viral goat dermatitis (Patnaik 1986), false blackleg (malignant edema), and enterotoxemia due to Clostridium perfringens type D. A nonpathogenic lymphoreticular hyperplasia of the epicardium and pericardium has also been seen histologically from slaughter surveys (Chattopadhyay and Sharma 1972). Hydropericardium has also been reported at necropsy in goats poisoned by consumption of the seed pods of the tree Albizia versicolor in Malawi. The predominant clinical picture was one of neurologic disease (Soldan et al. 1996). Incidental and subclinical myocardial lesions may include gray white foci of necrosis in the ventricles presumed to be caused by earlier plant or bacterial toxic insults, metaplastic cartilage development with or without calcification, focal lymphocytic infiltration of the myocardial interstitium, granulomatous myocarditis, and parasitic myocarditis. Causes of parasitic myocarditis include sarcosporidiosis, hydatid cysts, and metacestodes of other taeniid cestodes including Cysticercus and Coenurus (Bhalla and Nagi 1962; Chattopadhyay and Sharma 1972; Hein and Cargill 1981). Aortic abnormalities occur in goats, though in general they contribute little to clinical disease. These include aneurysm, aortitis media, melanosis, intimal fat deposits and intimal fibrosis, cartilaginous and osseous metaplasia, and calcification (Prasad et al. 1972; Geisel 1973). Migratory tracts, nodules, corrugations, aneurysms, and thickening of the aortic wall may be seen in association with onchocerciasis (Kaul and Prasad, 1989). Focal aortic necrosis and calcification in goats is a frequent lesion in caprine paratuberculosis (Majeed and Goudswaard 1971). Calcification of the aorta as well as other great vessels is seen in goats with enzootic calcinosis due to consumption of yellow oat grass (Trisetum flavescens), as described above.

SPECIFIC DISEASES OF THE CARDIOVASCULAR SYSTEM Heartwater Heartwater, also known as cowdriosis, is an infectious, non-contagious, tick-borne rickettsial disease of domestic ruminants. Historically restricted to subSaharan Africa, heartwater has more recently also been identified in the Caribbean. There is considerable concern about the possible spread of heartwater and its vector to tropical and subtropical regions of North, South, and Central America where, moreover, other suitable tick vectors exist. Etiology The causative agent is the rickettsia Ehrlichia (previously Cowdria) ruminantium. It is Gram-negative and stains reddish purple to blue in smears with Giemsa stain. Pleomorphism is common. Smaller organisms are usually coccoid while larger ones may be horseshoe, ring, or rod shaped. In mammalian hosts, the organism has a predilection for vascular endothelial cells. In the tick vector, it is found in intestinal epithelial cells and in cells of the salivary glands. Historically, efforts to perform in vitro cultures of E. ruminantium have failed, but successful cultivation of several strains of the organism on endothelial cell lines as well as tick cell lines is now possible (Bezuidenhout et al. 1985; Bell-Sakyi et al. 2000). Live organisms in whole blood or tissue homogenates from infected animals may be stored for extended periods by quick freezing in liquid nitrogen using a suitable cryopreservative, for example, dimethyl sulfoxide. Various strains of the organism exist. Cross-protective immunity may develop after infection with various field strains (Van Winkelhoff and Uilenberg 1981; Uilenberg 1983), but strains are often not or only partially cross-protective when used to challenge ruminants (Uilenberg 1983; Jongejan et al. 1988; Du Plessis et al. 1989), and antigenic diversity is an important feature of E. ruminantium. Field isolates often consist of more than one strain. Strains also vary in virulence, and there are isolates, indistinguishable from E. ruminantium using molecular methods, that do not cause clinical disease at all (Allsopp et al. 2007), and one of these has even been detected in a goat in the United States (Loftis et al. 2006). Epidemiology Heartwater is indigenous to sub-Saharan Africa. It was first recognized in South Africa in 1838 and is still considered a major obstacle to expansion and development of livestock enterprises on the continent. Imported cattle, sheep, and goats in particular are very susceptible to severe infection with high mortality rates.

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Heartwater is also found on islands near Africa, including Madagascar, Mauritius, Reunion, the Comoros and São Tome. The occurrence of heartwater in the Western hemisphere causes concern. The disease was reported on the island of Guadeloupe in 1980. Since that time, its occurrence on other Caribbean islands including Antigua and Marie Galante has been confirmed. The tick vector Amblyomma variegatum, originally introduced into the region with an importation of cattle from Senegal in the nineteenth or possibly even in the eighteenth century, has also been found on Puerto Rico, Vieques, St. Croix, St. Martin, Anguilla, St. Kitts, Nevis, La Desirade, Martinique, St. Lucia, St. Vincent, and Barbados, but E. ruminantium has not yet been identified on these islands (Camus et al. 1984). An international campaign for the eradication of A. variegatum from the Western Hemisphere, operational from 1994 to 2006, has succeeded on some of these islands, but failed in its ultimate objective (ICTTD 2006). The distribution of heartwater reflects the geographic distribution of the tick vectors of the genus Amblyomma that transmit the disease to domestic and wild ruminants. Amblyomma spp. are three-host ticks that feed on a wide variety of mammals and birds. The most widespread vector for heartwater in Africa and the Caribbean is A. variegatum, also known as the tropical bont tick. Other natural African vectors include A. hebraeum in southern Africa, A. pomposum in southcentral Africa, and A. gemma and A. lepidum in east and northeastern Africa. Several other African Amblyomma spp. may carry the organism but mainly feed on wild animals. At least two ticks found in North and South America, A. maculatum, the Gulf Coast tick, and A. cajennense, the cayenne tick, are capable of transmitting E. ruminantium to domestic ruminants, the former quite effectively (Uilenberg et al. 1984). In general, Amblyomma ticks can passage E. ruminantium transstadially but not transovarially, though there is one report of transovarial transfer. Consecutive passage from larval to nymphal stage, nymphal to adult stage, and larval to nymphal to adult stage occurs. Ticks therefore can remain infected for periods as long as several years. The organism resides in the intestinal epithelium of ticks and is thought to be transmitted with the saliva (Kocan and Bezuidenhout 1987). The hosts for E. ruminantium appear to be essentially members of the family Bovidae including both domestic and wild ruminants in Africa. Cervidae are also susceptible. Wild ruminants may serve as a reservoir for infection, but a wildlife reservoir is not necessary to sustain infection. Prolonged survival of E. ruminantium in ticks maintains the disease, and the carrier state in ruminants also occurs (Andrew and Norval, 1989).

An age-related resistance to disease occurs in young domestic ruminants, independent of maternally derived passive immunity. The period of resistance in calves and lambs gradually wanes after approximately the first three weeks of life. The period in kids is not well studied but may be even shorter. Young animals exposed during this period are unlikely to develop clinical disease and are resistant to subsequent homologous reinfection. Because the period of host resistance is short and the infection rate and/or number of the tick vectors may be low, the opportunity to develop an immune host population is limited, and serious disease losses can continue to occur in endemic areas. Goats are the most susceptible natural hosts based on epidemiologic observations and experimental challenge studies. Indigenous goats in endemic areas are more resistant than imported ones, but serious incidents of acute heartwater in local goats do occur in Africa (Aklaku 1980; Gueye et al. 1984). Very young, resistant goats may not be exposed to feeding ticks during their resistant period because of local variations in tick populations, preferential feeding by ticks on cattle over goats, or confinement of kids to villages to avoid theft and predation (Ilemobade 1977). A seroprevalence survey of heartwater in Red Maasai sheep and Small East African goats conducted at three sites in Narok District of Kenya using the MAP1-B ELISA found 62% to 82.5% of sheep and 42.5% to 52% of goats to be seropositive (Wesonga et al. 2006). Evidence for differences in breed susceptibility is suggested by epidemiologic and experimental observations. In South Africa, Angora goats and Boer goats are quite susceptible to heartwater compared with other indigenous or exotic breeds (Van de Pypekamp and Prozesky 1987). Breed differences in susceptibility have also been reported in Guadeloupe, with native Creole goats showing greater resistance than European breeds of goats. However, differences are also observed between different populations within a given breed based on their history of exposure to cowdriosis. It is presumed that genetic resistance increases over time by natural selection in the face of continued challenge by E. ruminantium and that such resistance may be a recessive sex-linked trait (Matheron et al. 1987). Pathogenesis E. ruminantium is introduced into the mammalian host by an infected tick while feeding. The early development of infection is not well clarified. It has been suggested that initial replication occurs in regional lymph nodes within macrophages and other reticuloendothelial cells. This is followed by a rickettsemic phase lasting one to four days accompanied by fever. The organism can be demonstrated to occur in the blood plasma as well as in neutrophils (Logan et al. 1987). Subsequently, the organism invades and

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multiplies in vascular endothelium throughout the body, particularly in the cortex of the brain. The ensuing vasculitis results in fluid and protein loss through capillaries with local edema and hemorrhage that, depending on the location and severity, accounts for the varied clinical and post mortem findings. The incubation period in goats after experimental intravenous inoculation is seven to fourteen days, or even shorter after a massive infective dose. Clinical Findings The incubation period to fever after natural ticktransmitted infection is usually from about two to as much as four weeks. There are four clinical forms of heartwater: peracute, acute, subacute, and subclinical. Their development depends on host susceptibility and virulence of the infective strain. Sporadic cases or epizootic outbreaks may occur. Goats most often experience peracute and acute infections. In peracute disease, affected goats develop a high fever and then suddenly collapse without warning followed by a period of convulsions or paddling lasting from minutes to several hours. The acute form may last from two to five days. The first signs are depression, anorexia, and high fever up to 105.8°F (41°C) accompanied by rapid, labored breathing and cessation of rumination. Auscultation of the chest may suggest pulmonary edema and muffled heart sounds due to hydropericardium. This is followed by nervous signs including bleating, hyperesthesia, muscle twitching, teeth grinding, excessive blinking of the eyelids, nystagmus, frequent urination and defecation, circling, and finally terminal convulsions. Ocular congestion and diarrhea may precede or accompany the nervous signs. Mortality in goats may reach more than 90%. Signs of subacute disease may be limited to fever, watery eyes, mucous nasal discharge, coughing, dyspnea, and possibly diarrhea and mild nervous signs. Subacute disease is most likely in previously exposed or naturally resistant animals. Subclinical infection, manifested by a transient fever, is uncommonly recognized in goats. Clinical Pathology and Necropsy A decrease in packed cell volume, hemoglobin, total plasma protein, and serum albumin are common findings in heartwater. The leukocyte response is variable in goats with either neutropenia and lymphopenia or lymphocytic leukocytosis reported (Ilemobade and Blotkamp 1978; Abdel Rahim and Shommein 1978). Hyperglycemia and lactic acidosis may be recorded terminally. Orange-yellow serum has been reported as a consistent finding in Angora goats affected with heartwater, but the observation has not been repeated in other breeds of goats.

Gross post mortem findings in goats include hydropericardium, variable degrees of hydrothorax, and pulmonary edema. Other possible signs are ascites, edema of lymph nodes, serosal hemorrhage, particularly of the heart, mucosal congestion of the gastrointestinal tract, and swollen kidneys. Splenomegaly, a common sign in other species, was not observed in experimentally infected goats (Ilemobade and Blotkamp 1978). Severe nephrosis is reported in Angora goats (Prozesky and Du Plessis 1985). Histologically, the disease is characterized by the presence of clusters of E. ruminantium in the vascular endothelium of virtually all tissues examined; brain cortex is the most reliable source and liver the least reliable. For rapid post mortem field diagnosis, squash preparations of Giemsa-stained cerebrocortical gray matter reveal blue- to purple-stained clusters of E. ruminantium in vascular endothelium. If removing the entire brain is problematic, cerebellar cortex obtained via the foramen magnum with a spatula or spoon is a suitable sample for examination, or cerebral cortex may be obtained after drilling a hole in the skull, even simply with a good-sized nail and a hammer. Proper precautions in rabies-enzootic countries should of course be taken. Diagnosis Diagnosis is presumptive, based on the clinical history and signs, the presence of Amblyomma ticks in the region and on the animal, and the demonstration of organisms in vascular endothelium on smears or histologic examinations as described above. Differential diagnosis for the peracute form of disease includes virtually all causes of sudden death in goats, discussed in Chapter 16. The acute or neurologic form of heartwater must be distinguished from tetanus, rabies, pseudorabies, organophosphate toxicity, and various plant poisonings. In particular, one leguminous tree, Albizia versicolor, occurs in areas of southern Africa where heartwater is endemic. Consumption of the seed pods by goats can produce both neurologic signs and hydropericardium, which are suggestive of heartwater (Soldan et al. 1996). When diarrhea and fever precede neurologic signs, peste des petits ruminants, rinderpest, and salmonellosis should be ruled out. Confirmation of heartwater in live animals has long been difficult because the organism cannot be cultured routinely. Intravenous inoculation of 5 to 10 ml of whole blood from suspected cases into known healthy, susceptible goats or sheep with subsequent necropsy of the ill test animal confirms the diagnosis. A technique for cerebral biopsy to examine brain smears from goats for E. ruminantium has been described (Synge 1978). It is most diagnostic three to six days after onset of fever (Camus and Barre 1987). At present

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the infection can be confirmed by molecular methods, specific DNA probes (Waghela et al. 1991), and PCR, which considerably increases sensitivity (Martinez et al. 2004). There are presently several serological tests for detecting antibodies to E. ruminantium, but all suffer to some extent from lack of specificity, as there are cross reactions with some other Ehrlichia species or unknown agents. This has partly been overcome by using more specific recombinant antigens instead of crude antigens for enzyme-linked immunosorbent assays (Van Vliet 1995, Katz et al. 1997; Kakono et al. 2003). A direct fluorescent antibody test is capable of detecting E. ruminantium in macrophage and buffy coat cultures of infected goats, sheep, and cattle (Sahu 1986). Challenges and advances in the laboratory and field diagnosis of heartwater have been recently reviewed (Mahan 2006). Treatment Successful therapy depends on early initiation of antibiotic therapy. Animals treated during the febrile stage of acute heartwater respond favorably to tetracycline, 5 to 10 mg/kg bw intravenously or intramuscularly administered at the first sign of fever and repeated one additional time either one or two days later. Long-acting oxytetracycline given one time intramuscularly at the onset of fever at a dose of 20 mg/kg is also effective. Therapy initiated after the onset of neurologic signs is almost always ineffective. Delaying treatment until after day two may result in poorer success because of development of severe nephrosis secondary to renal ischemia (Prozesky and Du Plessis 1985). Control Attempts to control heartwater by controlling tick populations in Africa have been somewhat successful, though eradication of the disease by vector control seems unlikely, and even the attempt at vector eradication from the Caribbean islands has failed A combination of controlled exposure and treatment has been used to vaccinate exotic livestock in Africa with some success. Infective materials used as vaccines are prepared by snap freezing of blood (or tissue preparations) derived from artificially infected livestock (or ticks). Because these are rather crude preparations, anaphylactic reactions can and do occur in a small percentage of vaccinates, and other pathogens may unintentionally be transmitted. For vaccination these substances are administered by the intravenous route. At the first sign of fever, vaccinated animals are treated with oxytetracycline (10 mg/kg intramuscularly or intravenously) to diminish the signs of disease and impart an immunity to reinfection.

Kids vaccinated during their period of natural resistance may not show a febrile response (Van der Merwe 1987). Because of the logistical difficulty of determining the onset of fever in individual animals, arbitrarily timed treatments after vaccination have been recommended. However, the time of onset of the febrile response depends on the strain and preparation of the vaccine. When Angora goats were monitored after vaccination with a frozen Ball 3 strain vaccine, 97% were in the febrile phase between day ten and day fourteen, while only 76% of goats given a fresh Ball 3 strain vaccine were febrile during that period (Erasmus 1976). Because successful vaccination depends on proper timing of treatment, the mean incubation period for the vaccine to be used should be known in advance if such block treatment is to be used. It may be several days shorter when tick filtrate vaccines are used. Temperatures in goats should reach 103.1°F (39.5°C) before treatment. The duration of immunity in goats is not well known but may be as short as two months. Field exposure to antigenically different strains may be responsible for a seemingly short duration of immunity, and homologous immunity is likely to be longer. Vaccination should be timed to precede periods of peak tick feeding activity in wet seasons. Vaccination procedures for cowdriosis have been reviewed (Van der Merwe 1987). At present there are ongoing studies on improving and standardizing the classical method of infection and treatment by using infective material obtained in cell culture, which would also largely solve the problem of spreading other pathogens. Other studies concern inactivated as well as attenuated vaccines. Advances in the development of new vaccines and vaccine methodologies for control of heartwater have recently been reviewed (Mahan 2006). Efforts to control tick populations on goats may help control cowdriosis. However, dipping of Angora goats during pregnancy or cold weather should be avoided because stress-related abortion and hypothermia are common in this breed (Gruss 1987). Schistosomosis Schistosomes are trematode parasites of the vascular system. Different species reside in the vasculature of different organs, and can produce a variety of clinical manifestations including rhinitis, enteritis, hepatitis, or pneumonia. All clinical forms occur in goats in endemic regions of the world. Etiology In the family Schistosomatidae are two genera that can cause clinical disease in goats: the Schistosoma and the Orientobilharzia. Numerous species use goats as a definitive host. These are identified in Table 8.3 along with their geographic distribution, intermediate and

8/Cardiovascular System 331 Table 8.3. Schistosomes reported to infect goats. Species

Geographic distribution

Intermediate snail host

Definitive hosts

Sites of localization

Clinical effects

Schistosoma bovis

Central, East, and West Africa; Mediterranean, Middle East Far East

Various Bulinus spp.

Ruminants, equines, camels, rodents, humans

Portal and mesenteric veins

Diarrhea, dysentery, anemia, emaciation, death

Various Oncomeliana spp.

Hepatic, portal, and mesenteric veins

Diarrhea, dysentery, anemia, emaciation, death

S. mattheei

Central, South, and East Africa

Various Bulinus spp.

S. spindale

Indian subcontinent and Far East Indian subcontinent

Various Planorbis, Lymnaea, and Indoplanorbis spp. Indoplanorbis spp.

Ruminants, equines, humans, pigs, dog, cats, rodents Ruminants, equines, humans, baboons, rodents Ruminants, rodents, and dogs Ruminants, equines, camels

Portal, mesenteric, urogenital, and stomach veins Mesenteric veins

Pneumonia, diarrhea, dysentery, anemia, emaciation, death Diarrhea, dysentery, anemia, emaciation, death Diarrhea, dysentery, anemia, dyspnea, emaciation, death

S. mansoni

Africa, South America, Middle East

Various Biomphalaria spp.

S. nasale

Indian subcontinent

Indoplanorbis and Lymnea spp.

S. incognitum

Lymnea spp.

S. curassoni

Indian subcontinent West Africa

Orientobilharzia turkestanicum

Mongolia, Iraq, France, Russia

Lymnaea euphratica

S. japonicum

S. indicum

Various Bulinus spp.

definitive hosts, and the site of localization within the goat. There is one report of finding Schistosoma incognitum in goats in a slaughterhouse survey in Jabalpur, India (Agrawal and Sahasrabudhe 1982), though this species is usually associated with swine. Experimental patent infection of goats with S. incognitum was later demonstrated (Gupta and Agrawal 2005). Schistosoma curassoni, previously thought to be synonymous with S. bovis, is now considered a distinct species infecting goats, sheep, and cattle (Verycruysse et al. 1984), though hybridization is known to occur between the two species (Rollinson et al. 1990). Ongoing phylogenetic studies are helping to clarify the relationships and classification of the pathogenic species of

Most important in humans; various rodents, wild mammals, including goats Goats, cattle, buffalo, sheep, horses Pigs, dogs, one report in goats goats, sheep, cattle Ruminants, camels, cats, equines

Hepatic, portal, mesenteric, pancreatic, and pulmonary veins Mesenteric veins

Diarrhea, anemia, dyspnea, emaciation, death

Nasal mucosal veins

Coryza, sneezing, dyspnea

Not reported; found at slaughter Diarrhea, dysentery, anemia, emaciation, death Chronic debilitation

Portal and mesenteric veins Mesenteric veins

Schistosomatidae (Snyder and Loker 2000; Webster et al. 2006). The schistosomes are elongated trematodes with distinct male and female forms that are found together in the host as mating pairs. The life cycle of schistosomes is indirect and involves aquatic snails as intermediate hosts. Though there are species variations in life cycle, the general pattern is as follows (Soulsby 1982). Adult schistosomes reside in the vasculature of the target organ of their definitive hosts. These organs are usually the liver, intestine, nasal mucosa, or urinary bladder. Gravid females lay eggs that pass through the vessel walls and gain entrance to the gut lumen, bladder lumen, or nasal passage. These eggs, which

332 Goat Medicine

may already contain live miracidia, hatch when passed into water. The miracidia are released and infect the appropriate species of aquatic snail, which serves as the intermediate host. Subsequent development in the snail occurs over a variable time period of thirty-eight to 126 days based on environmental factors. Two generations of sporocysts occur in the snail, leading to the formation of cercariae that are released from the snail back into water. When definitive hosts stand in or drink contaminated water, they are infected by the cercariae, either by penetration of the skin or the rumen wall. After entry into the definitive host, cercariae transform into schistosomula and are carried to the lungs and then the liver via the bloodstream over a period of one week. Schistosomula are usually present in the portal veins by day eight. Mating occurs in the portal vein and adults then migrate to the mesenteric veins where maturation and egg laying occur. When hyperinfection occurs, adult schistosomes may mature in the pulmonary vessels and lay eggs in the lung. Pulmonary schistosomosis due to S. indicum has been reported in goats in India (Sharma and Dwivedi 1976). In the case of S. nasale, maturation and egg laying occur in the vessels of the nasal mucosa and eggs are passed in nasal discharge. The prepatent period for S. bovis infection in goats was recorded as forty-seven to forty-eight days (Massoud 1973).

mostly through a strategy of prolificacy. Livestock are infected when they drink from, stand in, or wallow in such water sources. Additional factors contributing to an increased prevalence are poor grazing, limited water supplies, and overcrowding (Hurter and Potgieter 1967). The prevalence of schistosomosis in various livestock is largely dictated by their behavior relative to water. Pigs and buffalo, the wallowing species, have a high prevalence of infection; cattle, an intermediate prevalence; and sheep and goats, a low prevalence (Agrawal 1981). Goats show a distinct aversion to immersion in water, and even avoid walking through it. This may reduce their potential for exposure (Kassuku 1983). In abattoir surveys, prevalence of schistosomosis in goats is consistently much lower than in buffalo and cattle (Islam 1975; Kassuku et al. 1986). Nevertheless, serious losses of goats can occur, such as reported from China, where summer rains produce marked increases in intermediate host snail populations (Li 1987). It is fortunate that the goat is less frequently exposed to infection because when cattle, sheep, and goats are experimentally challenged with S. bovis or S. japonicum cercariae, the intensity and severity of infection is most profound in goats (Massoud 1973; Chiu and Lu 1974).

Epidemiology

The intestinal form of the disease occurs approximately two months after infection, when adults begin to lay eggs in the mesenteric veins and the spined eggs pass through the intestinal mucosa. This results in injury to all layers of the intestinal wall with hemorrhage and edema, and the formation of microabscesses, granulomas, and progressive fibrosis. These changes lead to diarrhea and dysentery and probably malabsorption, as hypoproteinemia is common. The adult parasites cause phlebitis in the mesenteric vessels and are sometimes also found in vessels of the urinary bladder and the pulmonary arteries. As many as 1,000 pairs of adults have been counted from the mesenteric veins of goats dying with S. mattheei infection (Hurter and Potgieter 1967). The hepatic form of the disease is considered to reflect a severe cell-mediated immune response to Schistosoma eggs refluxed back into the portal circulation. Soluble egg antigens induce a marked eosinophilic, granulomatous reaction leading to extensive damage to the portal vasculature and subsequently severe fibrosis of the portal triads (Soulsby 1982). In humans, especially, this results in portal hypertension with development of varices and possibly congestive heart failure. In ruminants, these cardiovascular effects are not expressed clinically and liver involvement is usually detected only at necropsy. It is reported that

Schistosomes infect humans and animals mainly in Asia, Africa, the Middle East, South and Central America, and the Mediterranean region. Schistosomosis, or bilharzia, is an important human disease in Africa, Asia, and South America, caused principally by S. haematobium, S. japonicum, or S. mansoni. Livestock, including goats, can serve as a reservoir for Schistosoma spp. infective for humans (Adam and Magzoub 1977). The intestinal form of schistosomosis in goats is reported most frequently from Asia and Africa. The nasal form, caused by S. nasale, is restricted to the Indian subcontinent. Economic losses because of schistosomosis in goats result from poor growth and performance, treatment costs, mortality, and condemnations, especially of livers, at slaughter (Singh Nara and Nayak 1972; Seydi and Gueye 1982). The occurrence of schistosomosis is closely tied to the ecology of the intermediate snail hosts. The snails thrive in stagnant or slowly moving water such as is found in irrigation ditches, rice paddies, watering tanks or troughs, shallow ponds or puddles, and ditches during seasons of heavy rain. As such, the occurrence of schistosomosis may be continuous or seasonal depending on the nature of the contaminated water source. Where occurrence is seasonal, snails persist through periods of decreased water habitat,

Pathogenesis

8/Cardiovascular System 333

O. turkestanicum infection in goats and sheep leads to chronic debility secondary to hepatic cirrhosis and intestinal granuloma formation (Soulsby 1982). Anemia occurs in schistosomosis as a result of hemorrhagic lesions in the intestinal wall from migration of eggs and from blood feeding by adults in the vessels. The nasal form of the disease represents an inflammatory reaction to the passage of eggs through the nasal mucosa and, to a lesser extent, the presence of adult schistosomes in the nasal vessels. The result is nasal congestion, copious nasal discharge, granuloma formation, and dyspnea. Pulmonary schistosomosis occurs when the host is challenged with large numbers of cercariae. Maturation of excessive numbers of schistosomes in the liver leads to spread of parasitic emboli back to the lungs. Adult schistosomes lay eggs in the lung vessels and produce multiple, diffuse, nodular granulomata throughout the lung parenchyma. Emaciation and respiratory distress result (Sharma and Dwivedi 1976). Clinical Findings All ages, breeds, and sex of goats are affected. Clinical disease occurs in association with the onset of egg excretion. In the intestinal form, diarrhea, anemia, and emaciation are the cardinal signs. The diarrhea is usually watery, but can be mucoid and/or bloody. Anorexia, dehydration, and edema are common accompanying findings. The clinical course is usually weeks to months and can result in death, chronic ill thrift, or sometimes spontaneous recovery. Clinically, the presentation may be indistinguishable from gastrointestinal nematodiasis. In the nasal form of the disease due to S. nasale, there may be weight loss, snoring, sneezing, copious mucoid or foul-smelling purulent nasal discharge, and dyspnea. In pulmonary schistosomosis, emaciation, and dyspnea can occur. The hepatic form of the disease is usually not recognized clinically; it is overshadowed by the enteric or pulmonary forms. Clinical Pathology and Necropsy Anemia and sometimes eosinophilia may be noted in the hemogram. Hypoproteinemia, hypoalbuminemia, and hypergammaglobulinemia may also be present (Pandey et al. 1976). In experimental S. mansoni infection of goats, there were elevations in serum arginase, AST, and bilirubin, and a depletion of liver glycogen (Adam and Magzoub 1977). To date, serological tests are generally unreliable for confirmation of individual cases or for prevalence studies, mainly because of cross reactions with other trematodes, notably Fasciola spp. and the amphistomes (rumen flukes), which are likely to be present in the same situations as schistosomes. Experimental infec-

tions of goats with S. japonicum have been confirmed serologically during the prepatent period using ELISA and immunofluorescent antibody techniques (Schumann et al. 1984). A dot ELISA test has recently been evaluated in experimentally and naturally infected goats in India (Vohra et al. 2006). Adjustments necessary to improve specificity of the test resulted in reduced sensitivity, but nevertheless, the test was considered to be potentially useful in the field for conducting prevalence studies in locations where infection status is unknown. In the field, confirmation requires identification of schistosome eggs in nasal secretions, nasal scrapings, feces, rectal scrapings, or possibly urine. Diagnosis by liver biopsy was also reported to be 100% reliable in goats, whereas fecal examination yielded many false negative results (Agrawal and Sahasrabudhe 1982a). Schistosome eggs are generally larger than nematode eggs. They are elongated and spindle shaped and possess a characteristic terminal spine. Direct smears or sedimentation techniques are preferred to flotation methods for finding these trematode eggs. Microscopic examination of squash preps of rectal mucosa obtained with a bowel forceps was 100% effective in diagnosing schistosomosis in a group of acutely affected sheep and goats (Hurter and Potgieter 1967). In chronic cases, egg shedding may be reduced and diagnosis may depend on identification of adult schistosomes in vessels at necropsy. For the diagnosis of caprine hepatic schistosomosis, it has been reported that egg hatching techniques are more sensitive for detection of eggs in the feces of affected goats than either the formal ether sedimentation technique or the alkaline digestion technique (Vohra and Agrawal 2006a). At necropsy, the carcass is usually emaciated. Adult schistosomes up to 30 mm in length are most frequently found in mesenteric, portal, intestinal submucosal and subserosal veins. They may also be found in pulmonary veins and veins of the urinary bladder. The liver may have a grayish discoloration and an uneven surface. The lungs may be enlarged, heavy, brownblack, and rubbery with multiple grayish nodular foci on the pleura and on cut surface when pulmonary schistosomosis is present (Sharma and Dwivedi 1984). A catarrhal enteritis is usually present and granulomatous swellings of the mucosa may be noted as well as areas of petechial or ecchymotic hemorrhage with accumulation of blood in the intestinal lumen. In the nasal form, large granulomas protruding from the nasal mucosa may be noted on cut section of the nasal passages. Histologically, lesions are associated primarily with eggs rather than adult schistosomes. Eggs in the liver, lung, intestinal wall, and nasal mucosa induce a marked inflammatory response with infiltration of eosinophils, lymphocytes, and macrophages.

334 Goat Medicine

Granuloma formation around schistosome eggs is common. The liver lesion is characterized by fibrosis in the region of the portal triads in advanced cases. Diagnosis The definitive antemortem diagnosis of schistosomosis depends on identification of eggs in excretions or by biopsy. The intestinal form of the disease must be distinguished from other causes of diarrhea in association with anemia and emaciation, notably gastrointestinal nematodiasis, coccidiosis, and fascioliasis. The nasal form of the disease must be differentiated from other causes of rhinitis as presented in Chapter 9. At necropsy, the diagnosis is confirmed by identification of adult schistosomes in the vasculature, or characteristic histologic lesions. Treatment In the past, the few drugs available to treat schistosomosis, such as antimony compounds, had narrow margins of safety and frequently produced toxic effects in goats and sheep. Haloxon was also reported to be effective in goats at a dose of 300 mg/kg against the intestinal schistosome S. mattheei with no noted side effects (Hurter and Potgieter 1967). Currently, praziquantel is being recommended for ruminants at an oral dose of 25 mg/kg bw repeated one time three to five weeks later. However, a single oral dose of 60 mg/kg was reported to effectively eliminate S. nasale infection from a goat with no toxic side effects noted (Anandan and Raja 1987). Control Efforts at control are directed at reduction of snail intermediate hosts and exposure of livestock to infective cercariae. When possible, stagnant water sources should be eliminated or fenced off and piped or running water provided instead. Water tanks and troughs should be emptied and cleaned periodically. When ponds or other stagnant water sources must be used, then snail control by application of molluscicides such as copper sulfate or niclosamide have been employed. To minimize effects on livestock, goats should be treated with praziquantel timed to peaks of likely incidence, such as two months after heavy rains. Currently there are no vaccines against schistosomosis.

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9 Respiratory System Anatomy 339 Clinical Examination of the Respiratory Tract 340 Respiratory Rate 341 Dyspnea 341 Externally Audible Sounds 341 Coughing 341 Nasal Discharge 342 Closer Examination of the Upper Respiratory Tract 342 Auscultation of the Lungs 343 Percussion of the Lung Fields 343 Blood Gas Measurement 343 Transtracheal Aspiration 344 Bronchoalveolar Lavage 344 Radiography of the Lungs 344 Ultrasonography of the Thorax 344 Lung Biopsy and Aspiration of Fluid from the Thorax 345 Effect of Environment on Respiratory Disease 345 Temperature 345 Ventilation 345 Animal Density 345 Building Construction 346 Upper Respiratory Tract Diseases 346 Rhinitis 346 Herpesvirus 346 Nasal Bots 346 Nasal Leech 347 Nasal Schistosomosis 347 Foreign Matter 347 Bacterial Rhinitis 347 Neoplasia 347 Pharyngitis 347 Abscessation of Retropharyngeal Lymph Nodes 347 Laryngitis or Tracheitis 348 Lower Respiratory Tract Diseases 348 Viral Causes of Pneumonia 348 Respiratory Syncytial Virus 348 Progressive Interstitial Retroviral Pneumonia 349 Ovine Pulmonary Adenocarcinoma, Sheep Pulmonary Adenomatosis, Jaagsiekte 350 Peste des Petits Ruminants 350 Goat Pox 351 Mycoplasma, Chlamydia, and Rickettsia Pneumonias 351 Nonspecific Mycoplasma Pneumonia 351 Contagious Caprine Pleuropneumonia 352

ANATOMY The structure of the lungs of the goat is illustrated in Figure 9.1. The lung is divided into bilateral cranial lobes (each with a cranial and a caudal part), a middle (cardiac) lobe on the right side, an accessory lobe of the right lung that extends ventrally on the midline, and bilateral caudal (diaphragmatic) lobes (ConstantiGoat Medicine, Second Edition Mary C. Smith and David M. Sherman © 2009 Wiley-Blackwell. ISBN: 978-0-781-79643-9

Pleuropneumonia 353 Chlamydiosis 354 Q Fever 354 Bacterial Pneumonia 354 Pasteurella and Mannheimia Pneumonia 354 Caseous Lymphadenitis Abscesses in the Lungs 356 Tuberculosis 357 Melioidosis and Rhodococcal Pneumonia 358 Fungal Pneumonia 358 Cryptococcosis 358 Other Fungi 358 Enzootic Pneumonia 358 Parasitic Pneumonia 359 Dictyocaulus Pneumonia 359 Protostrongylids 360 Eimeria and Other Protozoa 361 Echinococcosis, Hydatidosis 361 Liver Flukes 362 Schistosomosis 362 Inhalation Pneumonia 362 Nutritional Muscular Dystrophy 362 Iatrogenic Inhalation Pneumonia 362 Neurologic Causes of Dysphagia 362 Plant Poisoning 363 General Considerations Regarding Treatment and Prophylaxis of Pneumonia 363 Choice of Antibiotic and Duration of Therapy 363 Drug Dosage and Extralabel Use 363 Routes of Administration 363 Supportive Therapy 363 Pneumonia Prophylaxis 364 Pulmonary Edema and Pleuritis 364 Anaphylaxis and Fluid Therapy 364 Cardiac Disease 364 Pulmonary Disease 364 Pleuritis 365 Pulmonary and Thymic Neoplasia 365 Plant Poisonings Causing Acute Respiratory Signs 365 Cyanide Poisoning 365 Nitrate Poisoning 366 Devocalization 367 Traditional Surgical Technique 367 Electrosurgical Technique 367 References 368

nescu 2001). The right cranial lobe is supplied by a separate tracheal bronchus which originates before the bifurcation of the trachea. This lobe wraps around anterior to the heart and actually reaches the left side of the thorax. Subpleural lymph nodes 1 to 30 mm in diameter have been reported in the lungs of Angora and feral goats in New Zealand (Valero et al. 1993). 339

340 Goat Medicine Table 9.1. Some signs suggestive of respiratory disease and possible causes. Signs

Possible Causes

Dyspnea or Tachypnea

Anemia Pregnancy toxemia, ketosis Rumen acidosis Bloat Heatstroke Urolithiasis Nasal obstruction (tumor or foreign body) Progressive interstitial retroviral pneumonia (CAEV) Peste des petits ruminants Contagious caprine pleuropneumonia Pasteurellosis Septicemia Internal caseous lymphadenitis Tuberculosis Lungworms (Dictyocaulus) Nutritional muscular dystrophy Inhalation pneumonia Congenital heart malformation Cyanide poisoning Nitrate poisoning Other assorted toxicities Tight collar Tracheal stenosis Dusty or moldy hay Ammonia and other fumes Dysphagia (nutritional muscular dystrophy, neurologic disease) Contagious caprine pleuropneumonia Chronic progressive pneumonia (CAEV) Parainfluenza virus (PI3) Abscessed retropharyngeal lymph node Pasteurellosis Cryptococcosis Lungworms (Dictyocaulus) Heart failure Nose bots (Oestrus ovis) Powdery feeds Irritant fumes (ammonia, smoke) Cleft palate Regurgitation due to nutritional muscular dystrophy Atrophic rhinitis (toxigenic stains of P. multocida) Nasal adenoma Paste des petits ruminants, rinderpest Parainfluenza virus (PI3) Respiratory syncytial virus Caprine herpesvirus Pulmonary adenomatosis (jaagsiekte) Mycoplasma infections Pasteurellosis Melioidosis Cryptococcosis

Figure 9.1. Normal goat lung with trachea opened to demonstrate the tracheal bronchus supplying the right cranial lobe. (Courtesy of Dr. M.C. Smith.)

CLINICAL EXAMINATION OF THE RESPIRATORY TRACT Either a well-taken case history or basic physical exam may suggest the presence of respiratory disease. Signs noted might include increased respiratory rate, labored breathing, rapid tiring (especially with exercise), cyanosis, abnormal sounds associated with breathing, nasal discharge, coughing, or fever. Table 9.1 lists some of these signs and possible etiologies. If a respiratory disease is suspected, additional herd history is helpful in directing the diagnostic efforts. The owner should always be questioned concerning recent purchase or boarding of animals or attendance at shows, relative to possible introduction of infectious diseases. Do the goats get out of the barn, at least during part of the year? If not, lungworms and nasal bots are less probable. Is the herd known to be infected with or believed to be free of caprine arthritis encephalitis (CAE) virus, caseous lymphadenitis, and mycoplasma mastitis? Are housing and ventilation acceptable? The veterinarian should not accept the owner’s answer to this last question without personally inspecting the premises. Is the region seleniumdeficient, and is the ration supplemented with vitamin E and selenium? Has the animal been overdosed with injectable selenium, so that it is dyspneic because of heart failure? It is often impossible to obtain an exact and unquestionable etiologic diagnosis, at least in the living goat. This frustrates recent graduates whose education has suggested that the clever clinician always gets the right answer. On the other hand, more “experienced” practitioners may prescribe their favorite antibiotic for pneumonia rather than determine the cause of the clinical signs observed.

Cough

Nasal discharge

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Not every goat that breathes rapidly or “harshly” has respiratory disease. A complete physical examination always helps avoid embarrassing misdiagnoses. If the mucous membranes are white, think first of anemia, not pneumonia. Do not waste the owner’s money on tracheal washes and expensive antibiotics if the kid has an obvious heart murmur, at least not without explaining the seriousness of the underlying heart disease. Common pulmonary function tests have been adapted to the goat and normal values published (Bakima et al. 1988, 1990). This information should be useful to researchers evaluating respiratory disorders in goats or using goats as models in the study of respiratory physiology. Respiratory Rate The normal respiratory rate at rest is approximately ten to thirty breaths per minute (kids twenty to forty per minute). Few goats are “at rest” in the presence of an odoriferous stranger or after a long ride to the clinic in the back of a compact car. In addition, many normal goats pant; a respiratory rate of 270 per minute has been reported for goats held at 104°F (40°C). A goat with a long winter coat will certainly breathe rapidly if brought into a warm and humid room. A curious goat, continually sniffing the examiner, makes just the counting of the respiratory rate frustrating or even meaningless. The movements of the chest and abdominal wall should be observed from a distance, before the patient is disturbed. This is also the best time to note normal costo-abdominal respiration, abdominal pumping, or very shallow and painful chest movements (as with pleuritis). Many seriously ill goats have an increased respiratory rate because of fever, metabolic disturbances, or pain. Pregnancy toxemia, lactational ketosis, rumen acidosis, or diarrhea can all lead to metabolic acidosis. As part of the respiratory compensation mechanism, goats breathe faster to release carbon dioxide and thereby remove H+ (along with HCO3−) ions from the blood. Goats with listeriosis or other brain stem disease, on the other hand, may have an altered respiratory rate because of acidosis from loss of saliva or lesions in the respiratory centers of the brain. Metabolic alkalosis, which may be accompanied by very slow respiration, is less common in goats than in cattle, because most conditions associated with abomasal stasis (e.g., impaction, displacement, torsion, ulceration) are relatively rare. Dyspnea It is helpful to differentiate difficulty in breathing into inspiratory, expiratory, or mixed dyspnea. Strong outward movements of the thorax and longer inspiration are associated with inspiratory dyspnea.

Narrowed upper airway passages or bronchopneumonia with reduced respiratory surface in the lungs causes such a pattern. A distended head and neck and dilated nostrils accompany severe inspiratory dyspnea, and audible stenotic sounds may make location of an obstruction possible. With expiratory dyspnea, breathing out is impeded and is accentuated by strong and prolonged expiratory movements of the abdomen. This is less common in goats than in cattle because the caprine lung is not predisposed to interstitial emphysema. Cheek blowing or open mouth breathing with an extended tongue might accompany expiratory dyspnea. Logically, a mixed dyspnea occurs when there is difficulty in both inhaling and exhaling. Whenever the dyspnea is accompanied by cyanosis, the examiner should proceed cautiously to limit additional stress to the goat. If an upper airway obstruction is suspected, an emergency tracheostomy may become necessary. The heart must also be examined closely, because the cause of dyspnea may reside in the circulatory rather than respiratory system. Externally Audible Sounds Sneezing, a brief and powerful expulsion of air through the nose, occurs when the nasal mucosa is irritated by accumulations of secretions, exudates, or foreign matter. Stenotic sounds are caused by constriction in the upper respiratory tract. Snuffling sounds of nasal origin are usually loudest on inspiration. Alternate occlusion of one nostril and then the other helps to determine if the stenosis is unilateral or bilateral. That is, with a unilateral lesion, blocking the nostril on the affected side should decrease the sound while blocking the other nostril should increase the sound by forcing more air through the stenotic nasal passage. Sounds of pharyngeal origin are loudest on expiration, whereas laryngeal stenosis sounds are usually more pronounced on inspiration. Manual compression of the pharynx increases the loudness of pharyngeal sounds while decreasing laryngeal stridor. Sounds originating from a stenotic larynx are accentuated by additional compression of the larynx. If the stenosis is in the trachea, occlusion of one nostril or compression of pharynx or larynx decreases the air flow and the loudness of the stridor. Auscultation along the accessible portion of the trachea may permit localization of the lesion. The character of any stenotic sound (i.e., whistling, hissing, sawing) may be affected by the presence or absence of exudate in the airways. Coughing A cough may simply indicate irritation from fumes or dusty feed or compression of the trachea during attempts to reach something theoretically out of reach, such as the neighbor’s feed. If irritation lies in the upper respiratory tract, the cough is typically dry and

342 Goat Medicine

powerful. If the goat has a deep-seated bronchopneumonia, the cough may be moist and feeble. Coughing can be elicited by first briefly preventing respiration. This is done by holding a moist towel or similar object over the nostrils until the goat becomes distressed. When the nose is released, the number and nature of coughs are noted and the lungs are auscultated for abnormal respiratory sounds often accentuated by this procedure. Nasal Discharge Possible causes of a nasal discharge are listed in Table 9.1 or discussed under the topic of rhinitis below. Figure 9.2 shows a goat with a mucopurulent nasal discharge during a herd outbreak of infectious keratoconjunctivitis, possibly due to Mycoplasma conjunctivae (see Chapter 6). A purulent secretion is more significant than a serous discharge. A clear scanty bilateral nasal discharge is not unusual in adult goats in apparent good health. Clinically normal goats also harbor a wide variety of aerobic bacteria in their nasal passages, including Pasteurella multocida, Mannheimia haemolytica, and Streptococcus spp. (Ngatia et al. 1985). Closer Examination of the Upper Respiratory Tract It is useful to smell the breath; rotten odors may suggest the presence of infection or tumor in a sinus or along the airways. Compare with the smell of the open mouth. Some clinicians have the ability to detect ketone bodies on the breath; those who do not should keep a container handy to catch urine because the goat typically urinates on arising or after the stress or insult of close physical examination. If asymmetry in

Figure 9.2. Feed particles adhering to a mucopurulent nasal discharge. (Courtesy of Dr. M.C. Smith.)

airflow from the two nostrils is detected while smelling the breath or by holding the palm of the hand before each nostril, a tumor or foreign body may be present. The frontal and paranasal sinuses should be externally palpated and percussed. If the goat is hornless, the time and method of dehorning should be ascertained. If the goat does not eat hay and chew its cud freely, a tooth root abscess rather than a problem in the respiratory tract may be the source of a bad odor. Radiography may be helpful for diagnosing infections or tumors of the sinuses. When lesions in the pharynx or larynx are suspected, direct visualization is desirable. Light sedation with xylazine permits a good view of the back of the throat and the teeth. Manual exploration without sedation is hazardous at best. Naturally, in regions where rabies occurs, great care should be taken in all aspects of the physical examination. Do not neglect to palpate very carefully for the retropharyngeal lymph nodes. Their enlargement may occur with nonspecific local infections, but is more common with caseous lymphadenitis. A progressive dyspnea occurs because of external compression of airway (Jones and Schumacher 1990). Capripox infection can cause a similar obstructive lymph node enlargement in countries where this disease exists (Kitching 2004). Great care should be taken to avoid extending the neck during restraint for physical examination or diagnostic procedures; the increased compromise of the airway may be rapidly fatal. Endoscopic examination of the nasal passages, pharynx, larynx, and trachea has been performed in awake untranquilized adult goats using a 4-mm flexible endoscope and illustrations of findings in normal animals published (Stierschneider et al. 2007). The normal goat’s trachea may be drop shaped, round, or U-shaped in cross section. The trachea of a goat may be partially obstructed by a mass protruding into the lumen or by tracheal collapse. Coughing, stridor, and exercise intolerance are to be expected. Refrain from diagnosing a hypoplastic trachea without close comparison with healthy goats of the same age and size. That the caprine trachea is relatively small in diameter is well substantiated by the size of endotracheal tube typically required (see Chapter 17). Radiographic evaluation should be helpful in confirming stenotic tracheal lesions or compression from enlarged lymph nodes (Jones and Schumacher 1990). If localization of the problem is possible, excision of a mass or even placement of prosthetic tracheal rings may be attempted (Jackson et al. 1986). In confined groups of animals, a head tilt, sometimes accompanied by facial nerve paralysis, suggests the possibility of bacterial pneumonia. This is

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because organisms responsible for pneumonia can also ascend the eustachian tube and cause an otitis media/interna.

Breath sounds may be decreased with shallow breathing from pain, weakness, or central nervous disorders (Curtis et al. 1986).

Auscultation of the Lungs

Percussion of the Lung Fields

Much disagreement exists in the literature regarding terminology for normal and abnormal lung sounds. In addition, harsh inspiratory sounds may be heard over the entire lung field of a goat, especially a thin one, whether the lungs are normal or extensively altered by disease processes. The duration of expiration is also audible in goats, as in sheep. Special efforts should be made to auscultate well forward under the elbow, where cranioventral pneumonias are localized. Normal breath sounds are loudest on inspiration and are loudest over the trachea and base of the lungs. They are bronchial sounds; the velocity of airflow in alveoli is too low to generate audible sounds, and thus the terms “bronchovesicular” and “alveolar sounds” are inappropriate (Curtis et al. 1986). Increased breath sounds are heard in normal animals with increased rate and depth of respiration (i.e., excitement, exercise, high environmental temperature) or in goats with fever, acidosis, or pulmonary congestion. “Increased bronchial sounds” are heard on both inspiration and expiration. They occur in disease processes when the bronchial lumen remains open but the surrounding lung tissue transmits sound better because of being consolidated. This is true of most pneumonias of goats. There is no sharp line of demarcation between increased breath sounds and increased bronchial sounds. Crackles are clicking, popping, or bubbling sounds produced by fluid in the airways or by dry airways suddenly popping open. The term “crackles” can be used in preference to “moist rales” because it does not erroneously imply anything about the amount of fluid in the airways. Wheezes (also called rhonchi or dry rales) are whistling or squeaking sounds typically caused by the passage of air through a narrowed airway. Bronchospasm, abscesses, and tenacious exudate are possible causes of wheezes. Both crackles and wheezes may stop or move to another location, as when coughing dislodges fluid or exudate. Stridors (loud wheezing type sounds loudest over the trachea or larynx) may be referred to the lung fields, but they result from stenosis in the upper respiratory tract and are commonly audible without a stethoscope. Pleuritic friction rubs, described as “sandpaper-like sounds,” occur with severe inflammation of the pleura, assuming that adhesion or effusion does not prevent the rubbing. The absence of breath sounds may be simply because of obesity, as in some Nubians. Pleural effusion, pneumothorax, diaphragmatic hernia, and space occupying thoracic lesions (thymoma) are other possibilities.

In the past, the technique of finger-finger percussion or the use of a pleximeter has been more popular in Europe than in America. Thoracic percussion has been reviewed (Roudebush and Sweeney 1990). Veterinarians who expect to obtain useful diagnostic information from the procedure should routinely percuss many goats to become familiar with the normal sounds and lung boundaries. Percussion is usually done on the right side, although the presence of the spleen on the left makes it possible to identify the upper border between lung and rumen. The caudal lung border normally extends in an arc from the dorsal aspect of the eleventh intercostal space to the point of the elbow. A prescapular percussion field is present, and in thin animals the lungs can be percussed through the ventral portions of the scapula. Lifting a flexed forelimb to the side permits clearer percussion of axillary areas (Marek and Mocsy 1960). The full resonance of normal lung is to be contrasted with the more tympanic sound of gasfilled rumen or intestine, the relatively damped or dull sound of ventral abdominal organs, and the absolute dullness of the liver (on the right). A duller than normal sound over the lung fields can occur when large areas of the lung are consolidated by abscess, tumor, or interstitial pneumonia. The dull area is ventrally located and has a horizontal dorsal border if accumulation of fluid in the thorax is responsible. Processes causing increased intra-abdominal pressure (including late pregnancy) can displace the lung borders in a cranial direction. Blood Gas Measurement When laboratory testing is accessible, standard blood gas measurements give an indication of pulmonary function, as well as acid-base status of the animal. Venous blood is routinely collected in heparin, avoiding contamination of the sample with room air. Few studies specific to the goat have been published, and ideally each testing laboratory should determine the reference ranges for the apparatus being used, because some variability is to be expected (Kahrer et al. 2006). Time and temperature of blood storage before testing also influence test results. For instance, there is a slight decrease in concentration of HCO3− and a marked increase in pO2 with storage for twenty-four hours at 4°C (39°F), while pH is stable (Piccione et al. 2007). Blood gases determined by Blood Gas Analyzer on twenty-nine adult goats, one each from twenty-nine farms, are presented in Table 9.2 (Stevens et al. 1994). Respiratory acidosis, with increased pCO2 and HCO3−, is expected with impaired pulmonary function.

344 Goat Medicine Table 9.2. Blood gases of adult goats determined on venous blood. Parameter

Mean

2.5 percentile

97.5 percentile

pH pCO2 (mmHg) HCO3− (mmol/L) TCO2 (mmol/L) calculated pO2 (mmHg)

7.38 40.6 25.0 26.2

7.30 34.6 19.6 20.7

7.50 48.8 29.4 30.7

48.8

Transtracheal Aspiration The small diameter of the trachea makes this a more difficult procedure in goats than in cattle. Indications Transtracheal aspiration is useful for obtaining samples for cytology and bacteriologic culture in the diagnosis of an etiologic agent. Microbial sensitivity testing aids the choice of antibiotics to be used in treating a particularly valuable goat or one that has failed to respond to previous rational therapy. The frequency of recovery of pathogens from the trachea of goats when pulmonary disease is absent is unknown. Cultures from nasal swabs are of no diagnostic value relative to bacterial pneumonia. Technique The hair is clipped midway over the cervical trachea and a small bleb of local anesthetic is injected beneath the disinfected skin. Sterile gloves should be worn. A 14-gauge needle is used to penetrate the trachea and a 3 French polypropylene catheter or a 3 1/2 French tomcat catheter is passed into the trachea. A 16- or 18gauge intravenous catheter device may be used instead. The needle portion should be withdrawn after placement of the catheter into the trachea to avoid cutting off part of the catheter. Sterile, buffered saline (15 to 20 ml) is injected into the trachea. At once, as much as possible (often only a few milliliters) is aspirated into the syringe and submitted for microscopic examination and culture. The catheter is then removed. No special aftercare is needed. Bronchoalveolar Lavage In a hospital or research setting, better samples for cytology are obtained with the goat sedated (acepromazine at 0.3 mg/kg IV) or under general anesthesia and intubated. A tracheal wash catheter is passed through the endotracheal tube to the bronchial bifurcation. In an adult goat, approximately 50 ml of warm sterile saline is flushed into the lungs and then aspirated at once through the same catheter (Berrag et al. 1997). If available, recovery of fluid would probably be

improved by use of a pediatric bronchoscope. The authors report that in normal goats the predominant cell type recovered is alveolar macrophage (80% to 95%) with fewer lymphocytes, eosinophils, neutrophils, and epithelial cells. Radiography of the Lungs Radiography can document the presence of cranioventral bronchopneumonia, interstitial pneumonia, pleural effusion (often marked in contagious caprine pleuropneumonia), a penetrating metallic foreign body, thymoma, tracheal compression by enlarged mediastinal lymph nodes, or underlying cardiac disease leading to respiratory signs (Ahuja et al. 1985). The value of pulmonary radiographs often comes from confirmation of advanced and extensive changes in the lung fields. Multiple abscesses or massive areas of interstitial pneumonia suggest a very grave prognosis. Sternal and mediastinal lymph nodes should be examined for evidence of enlargement. Sternal abscesses with penetration into the thorax are accompanied by visibly enlarged sternal nodes and often by osteomyelitis of the sternebrae. Both viral and bacterial pneumonias, if chronic, can result in enlargement of mediastinal nodes. A large thymoma may displace the lungs caudally. Because many thymomas in goats are incidental findings at necropsy (Hadlow 1978), it is conceivable that an asymptomatic tumor might be identified during radiography of a goat with some other thoracic disease. If the lungs are displaced cranially, consideration should be given to a (very rare) diaphragmatic hernia (Tafti 1998). The radiographic equipment and techniques used for dogs are also appropriate for goats. The forelimbs need to be pulled well forward to expose the cranioventral lung lobes. Light intravenous tranquilization with xylazine (0.05 mg/kg), combined with clever use of tape and sandbags, provides safe restraint. Ultrasonography of the Thorax The physical or chemical restraint needed to obtain diagnostic radiographs of the chest may be dangerous to a severely dyspneic animal. Ultrasound examination can be done in a standing animal, usually at less expense than radiography. Scott and Gessert (1998) have described the procedure for sheep, and their findings should be applicable to goats. A sector scanner transducer rather than a linear array transducer is preferred because of the narrow intercostal space, and examination may not be possible in small goats. Hair is clipped from a 7 cm wide strip of skin caudal to the scapula and elbow bilaterally. Starting in the sixth or seventh intercostal space, the thorax is examined in longitudinal and transverse planes. The front limb is adducted and the clipped skin slid forward several

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spaces to allow access to the ventral aspect of the chest. Examination beginning from the ninth or tenth intercostal space assesses the dorsal lung field. Liberal wetting of the hair with alcohol can be substituted for clipping and application of an ultrasound gel. Normally aerated lung does not permit penetration of the ultrasound beam, so a bright linear echo and reverberation artifacts are all that are seen during examination of a normal animal. Ultrasound is useful for demonstrating fluid accumulation in the pleural space, abscesses that reach the pleura, tumors, and consolidation by bacterial or interstitial viral pneumonia (Scott and Gessert 1998). Lung Biopsy and Aspiration of Fluid from the Thorax If a fluid line is percussed in the thorax or detected by radiography or ultrasonography, thoracocentesis may be indicated. Clipping of hair and thorough disinfection of the skin are mandatory. A site beneath the fluid level but not directly over the heart should be chosen, and the needle should be kept close to the anterior edge of a rib to avoid nerves and blood vessels. Percutaneous lung biopsy (fine needle aspiration) is rarely performed but can be used to confirm the presence of an extensive interstitial pneumonia or tumor, as is associated with retroviral infections. The technique has been described in small animal medicine textbooks (Johnson 2005) and in sheep (Braun et al. 2000).

EFFECT OF ENVIRONMENT ON RESPIRATORY DISEASE The veterinarian should not be content with examining only the goat with respiratory disease. The environment should also be analyzed to determine if it is contributing to the pathogenesis of disease. Table 9.3

Table 9.3. Optimal housing for goats in temperate climates. Temperature

Relative humidity Ventilation

Lighting

Minimal 43°F (6°C) Optimal 50°F to 64°F (10°C to 18°C) Maximal 81°F (27°C) Optimal 60% to 80% Winter 30 m3/hour/goat Summer 120 to 150 m3/hour/goat Maximum air speed 0.5 m/s adults, 0.2 m/s kids Air intake at least twice surface area of air exit Window area equal to 1/20 of ground surface area

gives specifications for environmental conditions as recommended for milking goats in temperate climates (Toussaint 1984). Temperature At environmental temperatures above or below the optimal limits given in Table 9.3, the goat has to expend energy specifically to maintain its normal body temperature. As a consequence, production (milk or growth) is adversely affected. In a hot environment, the goat must decrease its heat production (eat less) while losing more heat through evaporation and radiation from lungs and skin. Under cold conditions, the goat must use more energy from feed or body reserves. It will also have increased levels of circulating glucocorticoids. Age and production level both affect the critical temperatures. For instance, the minimum temperature for kids is higher than for adults (Constantinou 1987). Indigenous breeds in many parts of the world are well adapted to more extreme conditions. Moderating the environment for these animals probably causes a loss of some degree of their genetic hardiness after a few generations. Ventilation Ventilation affects the purity of the air that the goats breathe. Heat, moisture, and carbon dioxide from the lungs need to be dissipated. Decomposition of feces and urine produces ammonia, hydrogen sulfide, methane gas, and other malodorous substances. A build-up of these chemicals can lead to irritation of the eyes and respiratory tract. Heaters and motorized equipment operating within the barn add to air pollution. Suspensions of dust from feeds and dirt carry with them numerous pathogens and saprophytic organisms. Coughing and sneezing serve to excrete many germs into the air in droplet nuclei (Ojo 1987), while dust helps to keep them airborne. Warm and humid conditions favor the survival of microorganisms in the air. Animal Density Overcrowding increases both the temperature and humidity in the barn because more goats generate heat and moisture into the atmosphere. Manure can also significantly increase the temperature. The surface area allotted per goat should be a minimum of 0.5 m2 per stanchioned animal and 1.5 m2 per adult in a free stall setting (Toussaint 1984). The minimum per unweaned kid is 0.3 m2. The minimum feed trough length recommended per goat is 0.4 m. With the inclusion of feed alleys, the typical area per goat in the barn is 2 to 2.4 m2. The height from the bedding to the ceiling then determines the volume per goat. If the ceiling is too low, temperature and humidity increase. If the air space is too great, the barn may be too cold in the winter.

346 Goat Medicine

Building Construction The building where goats are housed should serve several functions. First, it should shelter the animals from intemperate weather while providing a suitable microclimate for the goats. The comfort of the goat rather than of the owner is paramount. Second, the building should be constructed so that the owner can group animals as necessary and efficiently perform all the tasks required for management of the herd. The building and its equipment must not be so expensive that the owner cannot pay the mortgage. The barn should be situated where natural ventilation and drainage are good (top of a rise, not the bottom of a slope). In cold climates, exercise lots should have exposure to winter sun and a protective wall relative to prevailing winter winds. The barn should be situated away from wells and streams to avoid contamination of groundwater. Proper construction of the barn is required to obtain the desired ventilation rate, whether natural or mechanical ventilation is used (Constantinou 1987; Collins 1990). In particular, the placement and size of air inlets and fans are very important. The assistance of an expert in this field should be sought when designing a barn or attempting to correct a preexisting problem (Bates and Anderson 1979). Fans and air intakes must also be cleaned regularly to ensure continuing function of the ventilation system. Plastic netting may be used to temper prevailing winds. In cold climates, and in kid-raising facilities, insulation of the building avoids the stresses associated with large daily temperature fluctuations. While insulation prevents water condensation on the ceiling it requires more ventilation to remove moisture. A very serious error is the lining of the barn with plastic sheeting with the thought of keeping the goats comfortably warm. High humidity and dripping of condensed water onto the goats predisposes them to pneumonia. Leaky waterers also increase humidity, as does inadequate provision of new bedding. A last way that building construction can help to limit respiratory disease is in the provision of appropriate isolation facilities. Sick animals should be removed from the main pen, and purchased or boarded animals should be kept isolated from the herd for a minimum of two weeks. If attendance at shows is part of the operation of the herd, the traveling goats should be kept isolated from the stay-at-home animals for an equal time period, though this may in effect mean running two herds during the show season.

UPPER RESPIRATORY TRACT DISEASES As discussed earlier, clinical signs such as stertor, sneezing, nasal discharge, and cough suggest but are

not limited to conditions with upper respiratory tract involvement. Rhinitis There are several possible etiologies for inflammation of the nasal passages. Irritation from foreign material or parasites should be ruled out before more esoteric explanations are sought. A single mature goat in Brazil developed Prototheca-induced pyogranulomatous lesions of the skin at the nares and extending onto the nasal mucosa, causing inspiratory stertor, dyspnea, and weight loss (Macedo et al. 2008). This report underscores the importance of obtaining a biopsy sample from perplexing cases. Herpesvirus Caprine herpesvirus infection (see Chapter 12) has caused severe generalized signs, including bloody diarrhea, fever, dyspnea, and purulent nasal discharge. Fibrinonecrotic ulceration of the nasal septum occurred in one kid experimentally infected (Berrios et al 1975). In other experimental infections, the virus has caused a catarrhal rhinitis and mild tracheitis (Buddle et al. 1990a). Nasal Bots Nasal bots (Oestrus ovis) cause a chronic catarrhal to purulent discharge (Prein 1938) that may contain many eosinophils. This parasite is less common (larval burdens are smaller) in goats than in sheep (Dorchies et al. 1998). The adult fly deposits larvae around the nostrils of animals on pasture. First instars enter the nasal cavity and develop into second instars, which invade the sinuses of the head. Mature larvae return to the nostrils (if they have not grown too large to escape from the sinuses) after two to ten months and are expelled by sneezing (Kimberling 1988). Pupation occurs in the ground. Adult flies emerge after four weeks or longer, or possibly the next spring. Occasionally larvae are deposited about the eyes of humans, causing painful conjunctival ophthalmomyiasis (Cameron et al. 1991). Nose bots in goats can be suspected if nasal discharge is profuse and contains eosinophils. Frequent violent sneezing and avoidance behavior in late summer are typical. Caked-on dust leads to mouth breathing and interference with feeding, while inhaled bacteria and eosinophils may induce lung damage. Repeated infections induce a hypersensitivity and immunity in goats (Dorchies et al. 1998). Sometimes the bots are just an incidental finding in the sinus upon dehorning of adult goats. The condition can usually be ignored if it does not interfere with feed consumption. Various questionable products have been sprayed into the nasal passages in late fall and winter to kill larvae, including ruelene

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aerosol and concentrated lysol diluted 1:5 with water. Ivermectin (even at 0.2 mg/kg level) is highly effective against all stages of nose bots. A prolonged milk withdrawal of nine days is suggested if ivermectin is administered orally to goats producing milk for human consumption, and forty days if given subcutaneously (Baynes et al. 2000). Eprinomectin pour-on at 0.5 mg/ kg has been shown to be effective against Oestrus ovis in sheep (Hoste et al. 2004) and does not contaminate milk. Nasal Leech The nasal leech (Dinobdella ferox) infests ruminants grazing at altitudes of 900 to 1,800 m in the foothills of the Himalayas. The leeches live in permanent pools and springs; young leeches attach themselves to the nostrils of animals that drink there during the dry season. Leeches migrate to the nasal passages to feed but drop back into the water at the onset of the monsoon season (mid-June). Clinical signs include sneezing, blood-tinged mucoid nasal exudate, intermittent epistaxis, and anemia (Mahato et al. 1993). When leeches become large enough to protrude through the nostrils (fifteen days after infection) and restrict breathing, goats become restless and anorectic. Treatment is achieved by wetting the goat’s nostrils with water to encourage leeches to protrude, then permitting the leeches to dip their bodies in a (reusable) solution of 10 mcg/ml ivermectin. Leeches are expelled within a few hours after this therapy. Systemic ivermectin is not effective (Mahato 1989). Nasal Schistosomosis The blood fluke Schistosoma nasale has caused nasal obstruction in goats in India. This parasite is discussed in Chapter 8. Foreign Matter Foreign body rhinitis is often caused by powdery feeds. Regurgitation is a more serious possible cause. Assuming the absence of a cleft palate, nutritional muscular dystrophy (white muscle disease) should be considered whenever milk runs out a kid’s nose. This is discussed under inhalation pneumonia. Vagal nerve irritation in the abdomen or thorax or poisoning by plants of the Ericaceae (rhododendron) family may cause regurgitation through the nose and mouth, but the distinctive smell and green color of rumen contents on the muzzle make the identification of the irritating substance simple. Bacterial Rhinitis Atrophic rhinitis associated with toxigenic strains of Pasteurella multocida has been recognized in goats in Norway (Baalsrud 1987). Signs observed in affected herds include purulent nasal discharge, nose bleeding,

sneezing, and occasionally tender or distorted noses. Turbinate atrophy can be recognized when heads are sectioned at the level of the first premolar teeth. In tropical countries, purulent rhinitis with raised coalescing nodules on the nasal septum and turbinates has been observed in goats with melioidosis (Omar 1963). Neoplasia An enzootic nasal tumor of young adult goats has been reported from France and Spain and recognized in individual animals elsewhere in the world (Fontaine et al. 1983; Pringle et al. 1989; De las Heras et al. 1991a, 2003b). The lesion is unilateral or bilateral and papillary and results in lysis of the turbinates. Histologically, the tumor is benign. Retroviral-like particles have been demonstrated in the tumors of several goats that had negative agar gel immunodiffusion tests for maedivisna (and therefore CAE) virus (De las Heras et al. 1988, 1991a). Nasal secretions and the associated type D retroviral particles have transmitted the tumor experimentally (De las Heras et al. 1991b, 1995). Affected animals show profuse seromucous nasal exudate, coughing, dyspnea, and stertor. One or both eyes may protrude and pressure on softened cranial bones causes expulsion of mucous nasal exudate. The outcome is eventually fatal, the result of emaciation and asphyxiation (De las Heras et al. 1991a). Presumably, select cases might be amenable to surgical extirpation, as has been performed for nasal tumors of sheep (Rings and Rojko 1985, Trent et al. 1988). Lymphosarcoma can also invade the nasal sinuses of goats (Craig et al. 1986). A fungal granuloma caused by Cryptococcus neoformans has been reported to obstruct the nasal cavity of a goat in Australia (Chapman et al. 1990) and could be easily mistaken for a tumor. Pharyngitis Balling gun injuries can cause severe cellulitis in the region of the pharynx. Small plastic balling guns are particularly dangerous because the goats soon make them very rough by chewing on the plastic when bolus administration is attempted. Common clinical signs include cough, nasal discharge, and secondary inhalation pneumonia. The breath may have a foul odor, and the region of the pharynx is swollen and sensitive to palpation. Examination is simplified by tranquilization. Broad-spectrum antibiotics are given for treatment. Prevention typically involves using an alternative to anthelmintic or sulfonamide boluses. Abscessation of Retropharyngeal Lymph Nodes An enlarged retropharyngeal lymph node (Figure 9.3) may cause stertor, dyspnea, and coughing because of pressure on the pharynx or trachea. The mass can be detected by careful palpation and by radiography. The abscess is often caused by Corynebacterium

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Necrotic Laryngitis Fusobacterium necrophorum is a sporadic cause of laryngitis and of necrotic stomatitis in goats. The condition is discussed in Chapter 10. Cilia-associated Respiratory Bacillus

Figure 9.3. Abscessation of the retropharyngeal lymph node caused marked dyspnea in this goat. (Courtesy of Dr. J.M. King.)

pseudotuberculosis. A brave and careful surgeon is required to marsupialize the abscess without severing carotid artery, vagus nerve, or other important structures. Placement of a cuffed tracheostomy tube under local anesthesia has been recommended before induction of general anesthesia (Benson 1986). Caseous lymphadenitis is discussed in detail in Chapter 3. Laryngitis or Tracheitis These conditions are suspected when stridors are audible and can be localized to the corresponding portions of the upper respiratory tract. As discussed earlier, the trachea of a normal goat feels quite small. Common Causes Collars that press on the trachea may induce coughing in a tethered goat or one that is led by a collar. The cough is far less important than the danger of leg injury from the tether. Tracheitis because of irritants such as smoke, dust, whitewash, and ammonia in urine-soaked bedding has already been alluded to in the discussion of coughing. The diagnostician should get down to goat level and inhale deeply. If hay is dusty, the owner should try shaking it out while the goats are out of stall. If a goat is eating well and maintaining normal production and body condition, occasional coughing when fed or aroused is of no real concern. The possible role of Mycoplasma ovipneumoniae (see below) in chronic cough of otherwise healthy kids on certain farms remains to be studied. This cough is usually outgrown by about eight months of age. A single case of laryngeal hemiplegia has been reported in an adult Alpine goat (Tschuor et al. 2007). No etiology was determined, even with full necropsy and evaluation of the (normal) laryngeal nerve and musculature.

Recently, a Gram-negative filamentous bacterium called cilia-associated respiratory bacillus, or CAR, has been associated with respiratory tract disease in laboratory rodents and cattle. This organism has also been found by histological examination (Warthin Starry stain and immunohistochemistry) and electron microscopy in the trachea of kids and adult goats with chronic tracheitis (Fernández et al. 1996; Orós et al.1997a) and in the lungs of slaughtered goats with enzootic pneumonia (Orós et al. 1997b). The bacteria are interspersed with cilia and oriented perpendicular to the surface of the tracheal and bronchial epithelium. The significance of CAR in goats remains to be determined. Infectious Bovine Rhinotracheitis Infectious bovine rhinotracheitis (IBR) virus (bovine herpesvirus type I) is rarely isolated from goats, but experimentally causes pyrexia and mild clinical signs. Cough and nasal discharge would be expected if any signs at all occurred, although there is one report of severe respiratory disease (Mohanty 1972). The use of IBR vaccination is not recommended for goats. In fact, several caprine isolates have been indistinguishable from bovine vaccine strains (Whetstone and Evermann 1988). Goats may be latent carriers of the virulent bovine virus, potentially interfering with eradication attempts in cattle herds (Six et al. 2001).

LOWER RESPIRATORY TRACT DISEASES A clinician can only rarely be sure of the etiology of lung disease in a particular live goat. To make a more specific diagnosis than “pneumonia,” it is necessary to rely on the history of this or nearby herds or to await the proclamations of a microbiologist or pathologist (Ojo 1977). The etiology of pneumonia is usually multifactorial, and treatment often precedes diagnosis. A general discussion of therapy and prophylaxis for pneumonia, then, can be found following the discussion of etiologic agents.

VIRAL CAUSES OF PNEUMONIA Viral pneumonias in goats can be chronic or acute. Secondary bacterial infections are often superimposed. Respiratory Syncytial Virus A single caprine isolate of respiratory syncytial virus (RSV, a single stranded RNA pneumovirus of the family Paramyxoviridae, subfamily Pneumovirinae) has

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been characterized in the United States (Lehmkuhl et al. 1980). This isolate is very closely related to strains of bovine respiratory syncytial virus (BRSV) (Trudel et al. 1989). An RSV similar to BRSV has been isolated from goat kids with respiratory disease in Spain (Redondo et al. 1994). Clinical signs reported in this outbreak included fever, loss of appetite, conjunctivitis, nasal discharge, cough, and tachypnea. Animals with a simultaneous fibrinous Mannheimia haemolytica bronchopneumonia had higher fevers and more labored breathing. Crackles were heard over the lungs of all affected animals. Several surveys have documented antibodies against this virus or the closely related bovine RSV in healthy goats. This includes 36% of 112 adult goats from forty herds studied in Quebec (Lamontagne et al., 1985), 31% of 318 goats in twenty-two herds in another Quebec study (Elazhary et al. 1984), 50% of 332 goats in Louisiana (Fulton et al. 1982) and eleven of forty goats from farms in the Netherlands that also harbored cattle (Van der Pool et al. 1995). Goats in England were found to have antibodies against BRSV without ever having shown respiratory signs (Morgan et al. 1985), whereas goats seroconverted during a pneumonia outbreak in Zaire (Jetteur et al. 1989). The importance of RSV as a respiratory pathogen in goats remains unclear. There are no publications available concerning possible benefits of vaccination, although some veterinarians have used BRSV vaccines to prevent respiratory disease in show goats. Progressive Interstitial Retroviral Pneumonia Retroviruses (lentiviruses) are believed to cause both subclinical and fatal pneumonia in goats.

sheep (Dickson and Ellis 1989). Natural transmission of small ruminant lentiviruses between sheep and goats has been documented in mixed herds (Shah et al. 2004). Clinical Signs The first signs of dyspnea usually occur after a stress such as kidding or mastitis. The clinical course may be several weeks in advanced pregnancy or many months in the doe first affected after kidding. Exercise intolerance, dyspnea, and wasting often accompanied by a cough are prominent. Some but not all affected goats have enlarged carpi. Secondary bacterial pneumonias may be superimposed, and antibiotics often appear to give temporary relief. The pulmonary form of caseous lymphadenitis has a similar clinical appearance. Diagnosis Radiographs show small patches of interstitial pneumonia early in the course. A more advanced case is depicted in Figure 9.4 and elsewhere (Koenig et al. 1990). As debilitation progresses, large areas of lung are consolidated and bullous emphysema may damage the remaining lung parenchyma. Either caudal lung lobes or cranioventral lung lobes may be involved (Ellis at al. 1988a). At necropsy, the affected areas are swollen, grey-pink, and firm (Figure 9.5); numerous 1- to 2-mm whitish gray foci are visible on cut section as shown in Figure 9.6 (Robinson and Ellis 1984). Mediastinal lymph nodes are enlarged. Lung biopsies might confirm the diagnosis before death. Serologic testing is of no diagnostic value, but should identify an infected herd.

Etiology The caprine arthritis encephalitis virus (CAEV, viral leukoencephalomyelitis) has been reported to cause subclinical interstitial pneumonia (Cork et al. 1974). Occasional kids with neurologic lesions also have diffuse involvement of one or more lung lobes. A clinical syndrome indistinguishable from ovine progressive pneumonia and maedi-visna has been identified in CAEV-infected adult goats (Robinson 1981; Oliver et al. 1982). The sheep and goat viruses are still considered to be distinct by most researchers, but serologic tests cross react and both viruses are spread through milk, as discussed in Chapter 4. To date it has not been possible to reproduce this condition experimentally. Therefore there is a suspicion that an additional agent, such as a helper virus, may be involved. There is currently no evidence that the production of interstitial pneumonia depends on the strain of CAEV with which the goat is infected (Ellis et al. 1988b). Inoculation of CAEV into Merino lambs has failed to produce clinical disease in the

Figure 9.4. Pulmonary radiograph of a goat with interstitial pneumonia (Courtesy of Dr. M.C. Smith.)

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Figure 9.5. Goat lung with CAE interstitial pneumonia distending the diaphragmatic lobe. (Courtesy of Dr. M.C. Smith.)

Stefanou et al. 1975). The disease has been reported in sheep on all continents except Australia. The cause is an oncogenic beta-retrovirus (De las Heras et al. 2003a). Transmission appears to be via respiratory secretions. Experimental infection is much more difficult to produce in goats than in sheep (Sharp et al. 1986; Tustin et al. 1988). Clinically affected animals are mature and afebrile (in the absence of secondary bacterial infections) and show prolonged weight loss and dyspnea. Fluid accumulates in the lungs, which results in auscultable crackles or rales. A simple test used to differentiate the condition from chronic progressive pneumonia is to elevate the animal’s hindquarters. Fluid is expected to run out the nose if the animal is severely affected with adenomatosis. The disease is considered to be invariably progressive and fatal. There is no known treatment and no serologic test. Control is usually limited to culling goats that are wasting, although recently a PCR test for proviral DNA in leukocytes has permitted identification of subclinically infected sheep (Gonzalez et al. 2001). Removal at birth and artificial rearing on colostrum substitutes and milk replacer (essentially a CAE eradication program) has also been successful in creating a disease-free sheep flock (Voigt et al. 2007). At necropsy, many grayish nodules or extensive solid tumors are found in the lungs. The respiratory passages are filled with white froth. Histologically, there are alveolar and intrabronchiolar growths composed of masses of cuboidal and columnar cells. Metastases to regional lymph nodes have not been reported in goats (Sharma et al. 1975). Peste des Petits Ruminants

Figure 9.6. Cross section of an affected lung lobe, showing infiltration of the pulmonary parenchyma. (Courtesy of Dr. M.C. Smith.)

This important infectious disease of sheep and goats is also called PPR, stomatitis pneumoenteritis complex, and Kata (Hamdy et al. 1976). Etiology and Pathogenesis

Histological study of caprine progressive pneumonia reveals interstitial (peribronchiolar) accumulation of mononuclear cells and proliferation of type II pneumocytes. Alveoli are filled with an eosinophilic material that resembles surfactant when examined with the electron microscope (Robinson and Ellis 1984; Robinson and Ellis 1986). Discussions of the other CAEV-associated syndromes (i.e., arthritis, neurologic disease, mastitis) can be found elsewhere in this text. Control procedures are discussed in detail in Chapter 4.

The etiologic agent is a paramyxovirus of the Morbillivirus genus that is not pathogenic for cattle. The closely related rinderpest virus of cattle causes similar signs in goats. The two viruses seriously limit goat production in West Africa, the Middle East, India, and Southeast Asia. The virus is shed in secretions to infect other animals by direct contact. It can persist in the environment for as long as thirty-six hours, and thus holding pens can be a source of infection. The disease is discussed in detail in Chapter 10.

Ovine Pulmonary Adenocarcinoma, Sheep Pulmonary Adenomatosis, Jaagsiekte

Clinical Signs

This contagious lung tumor of sheep has been reported infrequently in goats (Rajya and Singh 1964;

The disease is characterized by fever persisting five to seven days and a profuse, even bloody diarrhea. Necrotic stomatitis, foaming at the mouth, and an

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ocular discharge are also noted. Pregnant animals may abort (Abu Elzein et al. 1990). Respiratory signs occur during the acute stages; these include malodorous, mucopurulent nasal discharge, frequent sneezing, increased respiratory rate, extended head, and mouth breathing. Severe leukopenia persists for ten days in animals that recover (Scott 1990). Some goats die two to three weeks later of a secondary bronchopneumonia (Whitney et al. 1967). The highest incidence of disease occurs during the rainy season, and goats most commonly affected are six to twelve months of age. Kids younger than three months of age usually have colostral immunity. Diagnosis Fluorescent antibody testing is useful for identifying the virus in nasal discharges and intestinal scrapings. Ocular or nasal discharges collected after two to three drops of phosphate buffered saline are placed in the eye or nostril can be used as the antigen in a hemagglutination test using 0.6% piglet red blood cell suspension (Wosu 1991). This test permits differentiation of peste des petits ruminants from simple bacterial pneumonia in live goats in situations where sophisticated laboratory facilities are not available. When available, a reverse transcriptase polymerase chain reaction test can be used to identify the virus in oculonasal swabs, oral lesions, or blood (Çam et al. 2005). Serological testing using a competitive ELISA also permits monitoring of the infection in endemic regions (Singh et al. 2004, 2006). The necropsy findings relative to the gastrointestinal tract are described in Chapter 10. There may be consolidation of cranioventral lung lobes. Histologic lesions reported in the lung include a giant cell pneumonia with eosinophilic intracytoplasmic inclusions in epithelial cells in perhaps half of the goats dying because of peste des petits ruminants. Less commonly there is necrosis of the tracheal epithelium. Diagnosis is complicated by secondary Pasteurella, Mannheimia, or Mycoplasma pneumonia. Prophylaxis Vaccination against this disease in endemic areas is both feasible (Gibbs et al. 1979) and economically sound (Opasina and Putt 1985). Prophylaxis is covered in Chapter 10. Hyperimmune serum (5 ml intravenously) reverses the signs of peste des petits ruminants if given during the febrile stage of the disease, when the temperature is 104.9°F (40.5°C) or higher. However, reinfection or relapse occurs after ten days and even those goats that develop labial scabs and appear to recover are susceptible to later challenge (Ihemelandu et al. 1985). Thus, goats treated with hyperimmune serum should still be vaccinated.

Goat Pox The capripox virus, discussed in detail in Chapter 2, causes systemic signs that include pyrexia, anorexia, and an arched back. Case fatality rates are increased when the respiratory tract is involved. At necropsy, multiple foci of consolidation (0.5 to 2 cm diameter) are commonly found beneath the pleura. These lesions may be hemorrhagic (Kitching 2004). Similar lesions may be seen in other organs such as liver, kidney, and abomasum. Secondary bacterial pneumonia is commonly the cause of death (Davies 1981).

MYCOPLASMA, CHLAMYDIA, AND RICKETTSIA PNEUMONIAS Of these organisms, mycoplasma are most frequently isolated and of the greatest economic importance. Several species of mycoplasma have been shown to cause pneumonia in goats (Hudson et al. 1967; Ojo 1987; Nicholas 2002). Some of these (belonging to the Mycoplasma mycoides cluster) cause specific syndromes known as contagious caprine pleuropneumonia and pleuropneumonia and are discussed separately. Because of changes in classification schemes, it is very difficult to interpret the older literature and to know exactly which organism was involved in a given report (Moulton 1980). Mycoplasma are generally fragile outside the host animal. They are easily inactivated by heat, sunlight, and disinfectants. Mycoplasma have been isolated from the external ear canal of goats (Ribeiro et al. 1997). Ear mites have been proposed as possibly disseminating the infection (Cottew and Yeats 1982; DaMassa 1983; DaMassa and Brooks 1991). Nonspecific Mycoplasma Pneumonia Several species are isolated sporadically from goats, either alone or in conjunction with other causes of pneumonia. Etiology and Pathogenesis Mycoplasma ovipneumoniae can be isolated from the trachea and lungs of healthy goats. When found in pneumonic lungs, the numbers of organisms present do not correlate with the severity of the lesion (Bolske et al. 1989). Fever and subacute fibrinous pleuritis have been produced experimentally with M. ovipneumoniae (Goltz et al. 1986), and natural cases also have been reported in goats (Livingston and Gauer 1979; Jones and Wood 1988). Production of a capsule may contribute to this organism’s pathogenicity (Niang et al. 1998). It lacks the “fried egg” colony appearance typical of other mycoplasmas when grown on solid medium (DaMassa et al. 1992). Note that M. ovipneumoniae may accompany other mycoplasma species that are more pathogenic but also more difficult to isolate.

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Oral administration of M. capricolum (M. capricolum subsp. capricolum) causes acute pneumonia and polyarthritis in kids via the septicemic route (DaMassa et al. 1983b, 1992; Bölske et al. 1988; Taoudi et al. 1988). The pneumonia is only rarely accompanied by pleurisy. The organism can then spread to contact kids, probably via respiratory secretions. Mycoplasma agalactiae, which typically causes mastitis in sheep and goats, has been shown capable of causing pneumonia in kids (Guha and Verma 1987). Mycoplasma arginini is isolated occasionally but is of doubtful pathogenicity (DaMassa et al. 1992). Mycoplasma bovis has been isolated from the lungs of goats, and could potentially have been acquired by consumption of milk from infected cows (DaMassa et al. 1992).

once daily) are considered to be superior to tetracycline in the treatment of pulmonary mycoplasmosis. Adverse reactions associated with intramuscular injection of these drugs include lameness and collapse. Side effects may be reduced by diluting the drug with an equal quantity of sterile saline solution just before injection or administering the drug subcutaneously. The newer macrolide drug tulathromycin, which has a prolonged pulmonary half-life and activity against bovine mycoplasma, has not yet been evaluated in small ruminants. Isolation of infected animals is desirable, but very difficult in free-ranging systems, especially where communal water holes are used. Control measures used for pleuropneumonia are applicable if herd outbreaks occur.

Associated Clinical Syndromes

Contagious Caprine Pleuropneumonia

In addition to respiratory disease, other conditions associated with mycoplasma include polyarthritis, mastitis, conjunctivitis, and keratitis (see Table 4.3). This combination of clinical signs has been termed the MAKePS syndrome, standing for mastitis, arthritis, keratitis, pneumonia, and septicemia (Thiaucourt and Bölske 1996). The differential diagnoses of these syndromes are considered elsewhere in this text.

Contagious caprine pleuropneumonia (CCPP) is a disease that naturally infects only goats, not sheep. Lesions are confined to the respiratory tract (Harbi et al. 1983). The disease is notifiable to the OIE (Office International des Epizooties).

Diagnosis Thoracocentesis has been suggested for the diagnosis of mycoplasmal pneumonia in living goats. Pleomorphic coccoid, ring, and filamentous organisms can be seen with the dark field microscope or, alternatively, after staining with a 5% nigrosin solution (Ojo 1987). Although special media are required, the MAKePS mycoplasmas (including those that cause pleuropneumonia, see below) grow on modified Hayflick’s mycoplasma medium (Rosendal 1994). It is relatively easy to isolate mycoplasma from acute cases, but difficult or impossible to culture the organism from chronically infected goats. Swabs should be shipped in transport media (without charcoal), refrigerated but not frozen. Tissue samples from the interface between consolidated and unconsolidated areas are chopped or pulverized in culture medium. Peribronchiolar lymphocytic infiltrations and diffuse nonsuppurative pleuritis at necropsy are suggestive of mycoplasma, but secondary pasteurellosis complicates the diagnosis. Serologic tests are not available for many mycoplasmal species, and in fact few laboratories are capable of typing mycoplasma isolates to determine if a known pathogenic species is present.

Etiology and Pathogenesis Mycoplasmologists have reclassified the etiologic agent several times (Martin 1983). In the 1980s the organism was specified as the highly fastidious F38 biotype Mycoplasma (McMartin et al. 1980), but currently it is named Mycoplasma capricolum subsp. capripneumoniae (Thiaucourt and Bölske 1996). Previously, M. mycoides subsp. capri was cited as the cause of CCPP, but now the disease associated with the latter organism is designated as pleuropneumonia, as discussed below. Although not identified in the Western Hemisphere, CCPP is prevalent in Africa, Turkey, the Middle East, and Asia (Thiaucourt and Bölske 1996). The organism is transmitted by aerosol during cohabitation and is highly contagious. The incubation period is typically six to ten days or longer. All ages are affected. Clinical Signs and Diagnosis In countries where this infection occurs, the signs are considered to be specific enough to permit an easy clinical diagnosis (Ojo 1987). These signs include fever, cough, and a painful respiration with grunting and the forelimbs held widely separated. The head is held low, there may be a frothy nasal discharge and salivation, and the goat is unwilling to move. Death occurs within two to ten days after onset of clinical signs. Typically there is a 100% morbidity rate and as much as 50% to 100% mortality rates in a susceptible flock (Ojo 1977).

Therapy

Necropsy Findings and Diagnosis

Penicillin and related drugs are ineffective because mycoplasma lack a cell wall. Tylosin (10 to 20 mg/kg once daily) and tiamulin (Ojo et al. 1984) (20 mg/kg

Serofibrinous pleuritis results in accumulation of straw colored pleural fluid. Pneumonia usually causes hepatization of entire lobes and is often unilateral. The

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lung appears granular or variegated, with red, yellow, white, and gray foci. Several reports include color photographs (Kaliner and MacOwan 1976; Thiaucourt et al. 1996; Nicholas 2002). There is extensive bronchoalveolar cellular exudate. In contrast to the findings in goats with pleuropneumonia caused by other organisms, there is no thickening of the interlobular septa (Thiaucourt et al. 1996; Nicholas 2002). The isolation of the CCPP mycoplasma is difficult and requires special media. Techniques have been described elsewhere (Rosendal 1994; OIE 2004). The agent can be identified by immunofluorescence, growth inhibition, or metabolism inhibition tests (U.S. Animal Health Association 1998). Serologic cross-reactions and similarity in biochemical tests can cause confusion in distinguishing M. capricolum. subsp. capripneumoniae from M. capricolum subsp. capricolum (Jones 1989). Paired serology with samples taken three to eight weeks apart is useful for diagnosing the disease in animals that recover, but in acute cases death typically occurs before seroconversion (OIE 2004). A latex agglutination test for field detection of antibodies to M. c. subsp. capripneumoniae polysaccharide antigen has been reported to be specific for CCPP in goats (Rurangirwa et al. 1990). A PCR testing scheme, when available, is considered conclusive (Hotzel et al. 1996) unless the disease has not been diagnosed in the country before. A very important advantage of the PCR testing is that a sample of pleural fluid from an untreated sacrificed animal can be allowed to dry on filter paper and then transported to a reference laboratory without having to maintain a constant “cool chain.” In countries where CCPP exists, the disease must be differentiated from other or coexisting infections such as pleuropneumonia caused by other mycoplasma infections, peste des petits ruminants, pasteurellosis, heartwater, and goat pox. Treatment and Control As with other mycoplasma, treatment with tylosin, tetracycline (El Hassan et al. 1984), tiamulin, or streptomycin (30 mg/kg) (Rurangirwa et al. 1981) is recommended. When tylosin (11 mg/kg), oxytetracycline (15 mg/kg), chloramphenicol (22 mg/kg), and penicillin plus streptomycin (dose per kg not indicated) were compared experimentally, tylosin caused more rapid recovery than oxytetracycline, while fevers were more persistent and some deaths occurred with the other two treatments (Onoviran 1984). More recently, fluoroquinolones have also been found to be effective against caprine mycoplasmas (Al-Momani et al. 2006) but their veterinary use is discouraged or forbidden in food animals because of importance of the antibiotic class in human medicine. Treatment should be continued for five days or provided with a long duration product (Thiaucourt et al.

1996). The prognosis for recovery with prompt treatment is approximately 87% (Rurangirwa et al. 1981; El Hassan et al. 1984). Animals recovered from clinical disease may remain carriers (El Hassan et al. 1984) and spread the disease to other herds. One study found dihydrostreptomycin-treated goats did not remain carriers (Rurangirwa et al. 1981) but use of this antibiotic is discouraged because of rapid development of resistance (Lefèvre and Thiaucourt 2004). Farmers usually retain animals that survive the infection. An experimental vaccine has shown good protection for as long as one year after a single immunization (Rurangirwa et al. 1987). Vaccination of 10,000 goats in Kenya with an inactivated F38 vaccine was followed by cessation of reported losses to CCPP after three weeks. None of 400 closely monitored goats showed any evidence of clinical CCPP during the six-month period after vaccination (Litamoi et al. 1989). A commercial vaccine is currently available in Kenya (OIE 2004). Pleuropneumonia Etiology Currently two different species of mycoplasma (M. mycoides subsp. capri and M. mycoides subsp. mycoides Large Colony [LC] or caprine type) are believed to cause very similar syndromes known as pleuropneumonia (Pearson et al. 1972). Earlier reports of M. mycoides subsp. capri from the United States probably reflect a misidentification of M. mycoides subsp. mycoides LC (DaMassa et al. 1984). Mycoplasma mycoides subsp. capri has been isolated from a high mortality respiratory outbreak in goats in Mexico (Hernandez 2006). A closely related species, Mycoplasma mycoides subsp. mycoides Small Colony type (the cause of contagious bovine pleuropneumonia), has been isolated from pneumonic lungs of goats in Africa (Kusiluka et al. 2000). Clinical Signs Incubation is from two to twenty-eight days, depending on virulence. Clinical signs include high fever, cough, painful dyspnea, increased nasal secretion, ear droop, and anorexia. Morbidity rates are near 100%, but mortality rates vary with the organism, less than 40% for the large colony type and close to 100% for the M. m. capri subspecies. Since the discovery of Mycoplasma capricolum subsp. capripneumoniae (F38 biotype), mortality rates attributed to M. m. capri have been questioned (Jones 1989). Diagnosis In the pleuropneumonia caused by M. mycoides subsp. mycoides LC, which is common in California, the organism is easily isolated from many internal organs

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and from joints and milk. The lungs of fatal cases are enlarged and firm. There is hepatization of cardiac and diaphragmatic lobes and marked pleural effusion and fibrinous pleuritis (Thigpen et al. 1981; DaMassa et al. 1986, 1992; Rodriguez et al. 1995). Both subspecies cause similar histopathologic changes; pulmonary edema is extensive and interlobular septa are distended and pale. Arterial and arteriolar vasculitis with necrosis of vessel walls and thrombi formation are seen (Jones 1989). Mycoplasma mycoides subsp. mycoides LC is less fastidious in its growth requirements than many mycoplasma and can be isolated on blood agar. Growth is slow, beta hemolysis appears by day six or seven, and colonies have a “fried egg” appearance (DaMassa et al. 1983a). Biochemical characteristics and antisera can be used to differentiate the various mycoplasma causing pleuropneumonia and contagious caprine pleuropneumonia, but a polymerase chain reaction scheme has also been devised for differentiating these organisms (Hotzel et al. 1996). Treatment and Prevention Kids are often infected by ingestion of milk, and the entire kid crop may be infected by pooled colostrum or milk (DaMassa et al. 1983a). Pasteurization of milk is routinely suggested to control an outbreak. Kids should be raised isolated from adults. Burning or deep burial of placentas and stillborn kids is also important. Tylosin (11 mg/kg intramuscularly for five days to two weeks) has been reported to be more rapidly effective for treatment than oxytetracycline at 15 mg/kg. Ear mites, which may spread mycoplasma to additional animals or herds, can be controlled with ivermectin (see Chapter 2). Chlamydiosis The role of chlamydia in caprine pneumonia is very unclear. A serious outbreak of pneumonia in goats in Japan seemed to originate with goats imported from the United States after World War 2 (Omori et al. 1953; Saito 1954). Elementary bodies of various sizes were seen in bronchial epithelial cells and stained by the Machiavello stain. An agent was isolated in embryonated eggs that caused mild chronic respiratory signs such as slight cough, nasal discharge, and fever after intratracheal inoculation, although secondary bacterial infections were often fatal. Experimentally infected goats were successfully treated with tetracycline (7 mg/kg intramuscularly for eleven days) (Ishii et al. 1954). A cough without dyspnea or nasal discharge developed in two of eleven goats experimentally inoculated with an abortion strain of Chlamydophila abortus (C. psittaci) and persisted one to two months in another study (Rodolakis et al. 1984).

Texas researchers have proposed that chlamydia are usually primary, with Pasteurella and mycoplasma causing a secondary pneumonia (Sharp et al. 1982). This theory does not seem to be commonly espoused, except perhaps in India. Fluorescent antibody tests, as have been used for diagnosis of abortion caused by chlamydiosis, would be a useful tool for additional study of the importance of the organism in pneumonia outbreaks. In a slaughterhouse study in India involving 3,799 apparently healthy goats, chlamydia were identified from fourteen of 218 (6.4%) pneumonic lungs by fluorescent antibody tests (Rahman and Singh 1990). Special stains identified elementary bodies in only eight of these cases. Gross lung lesions were mostly cranioventral. Histologically, there was an interstitial pneumonia and macrophages filled alveoli. Additional slaughterhouse studies have identified chlamydia in lung lesions of unknown clinical relevance by special stains or fluorescent antibody tests (Chauhan and Singh 1971; Patnaik and Nayak 1984; Kumar et al. 2004). Too little is known about the condition to formulate control programs. Different chlamydia serotypes are incriminated from those included in anti-abortion vaccines. Long-lasting oxytetracycline would be appropriate for therapy if involvement of this agent were suspected in field cases of pneumonia. Q Fever Q fever, caused by Coxiella burnetti, is occasionally associated with abortion in sheep and goats but is otherwise considered to be nonpathogenic for livestock. Its importance is as a zoonosis. However, experimental intrapulmonary or intranasal inoculation has produced febrile bronchopneumonia in goats (Caminopetros 1948). Kids from an abortion outbreak have also shown nonsuppurative interstitial pneumonia (Moore et al. 1991).

BACTERIAL PNEUMONIA Pasteurella and Mannheimia Pneumonia Pneumonic pasteurellosis is a cranioventral fibrinous bronchopneumonia. The disease occurs in goats throughout the world. Etiology Both Pasteurella multocida and Mannheimia (previously Pasteurella) (Angen et al. 1999) haemolytica cause pneumonia in goats (Ojo 1977). Both species are Gramnegative, tiny, ovoid rods that do not form spores. They grow well on blood agar, where only P. haemolytica causes hemolysis. Colonies are 1 to 2 mm in diameter. Pasteurella multocida but not M. haemolytica produces indole.

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Mannheimia (Pasteurella) haemolytica was previous divided into two biovars: biovar A, which ferments arabinose, and bivoar T, which ferments trehalose (Bingham et al. 1990). Subsequently, the T biovar was designated as Pasteurella trehalosi, and then the organism was assigned to a new genus, becoming Bibersteinia trehalosi (Blackall et al. 2007). How this might clarify the epidemiology of pasteurellosis in goats remains to be determined. The trehalosi organism has been cultured from the pharynx of healthy pack goats (Ward et al. 2002). A biotype T isolate obtained from an acute fatal case of caprine pneumonia has been used to experimentally produce a proliferative and exudative pneumonia (Ngatia et al. 1986). Biotype T Mannheimia haemolytica has also been cultured in association with an outbreak of contagious caprine pleuropneumonia in Ethiopia (Shiferaw et al. 2002). When typing has been performed of Mannheimia isolates from goats with pneumonia, M. haemolytica type A2 has been reported most frequently (Fodor et al. 1984; Midwinter et al. 1986; Hayashidani et al. 1988). Epidemiology and Pathogenesis Both of these organisms commonly reside in the upper respiratory tract of normal goats. While a previous viral infection would increase the probability of lung invasion by Pasteurella or Mannheimia, field conditions often provide enough stress for the organism to be a primary pathogen. Poor ventilation is a major factor permitting invasion of the lungs, but crowding, parasitism, and malnutrition all contribute to development of disease (Brogden et al. 1998). Some affected goats have been recently stressed by transport (Mugera and Kramer 1967), and steroid administration appears to increase the proliferation of M. haemolytica in the nasal passages of transport-stressed goats (Jasni et al. 1991). The virulence of the Pasteurella organism is either very high or increases during an outbreak, so that the disease may spread to unstressed herd members (Pande 1943). In other instances, pneumonia is recognized only in animals exposed to newly introduced goats (Hayashidani 1988; Buddle et al. 1990). A ruminant-specific leukotoxin produced by M. haemolytica is believed to be very important in the pathogenesis of pasteurellosis (Shewen and Wilkie 1985; Zecchinon et al. 2005). This toxin impairs and lyses alveolar macrophages and neutrophils that arrive in the lung to fight the infection. Enzymes released by the dying neutrophils cause additional injury to lung tissue. The deleterious effects of other toxins and cellassociated products of M. haemolytica have been reviewed (Brogden et al. 1998). Clinical Signs In the acute case, there is typically a fever of 104°F to 106°F (40°C to 41.1°C) and also mucopurulent nasal

and ocular discharge. Lethargy, anorexia, dyspnea, and a moist, painful cough are noted. Auscultation may reveal crackles, areas of consolidation (increased bronchial tones), or pleuritis (friction rub early, muffled sounds later). Mortality rates may be 10% or more. Commonly, one goat is found suddenly dead before any are noticed to be ill (Borgman and Wilson 1955; Mugera and Kramer 1967). Diagnosis and Post Mortem Lesions Diagnostic cultures may be obtained from tracheal washes or from necropsy specimens. Cultures taken from the nasal passages are not acceptable substitutes. Kids with acute pasteurellosis often have a septicemia, and bipolar organisms may be visible in stained blood smears (Ojo 1987). A radiographic examination documents the cranioventral distribution and rules out the presence of a penetrating metallic foreign body from the reticulum, which rarely acts to introduce infection into the thoracic cavity (see Chapter 10). At necropsy, the cranioventral lung lobes are usually affected bilaterally. There is a red to purple consolidation of these lobes, sometimes accompanied by a fibrinous pleuritis (Figure 9.7). Histologic changes are typical of pasteurellosis in other species and include hemorrhage, necrosis, and exudation of fibrin, edema fluid, and neutrophils or macrophages into airways. A Pasteurella or Mannheimia infection may be secondary to an interstitial pneumonia or possibly may upregulate the CAE virus when macrophages are activated in the lung. If poor body condition suggests that a dead goat has been ill for weeks or months, the dorsal lung lobes should be palpated very carefully. If they seem firmer than normal, histological examination to detect concurrent interstitial pneumonia should be requested.

Figure 9.7. Cranial ventral localization of a Mannheimia pneumonia with marked fibrinous pleuritis. (Courtesy of Dr. M.C. Smith.)

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Treatment and Prevention Antibiotics commonly used for parenteral treatment include penicillin (20,000 to 40,000 IU/kg once daily), ampicillin (5 to 10 mg/kg twice daily), tetracycline (5 mg/kg once or twice daily), tylosin (10 to 20 mg/kg once or twice daily), ceftiofur (1.1 to 2.2 mg/kg daily), and florfenicol (40 mg/kg every one to two days SC). A sample for culture obtained by tracheal wash or at necropsy should be submitted for sensitivity testing when dealing with herd outbreaks, chronic cases, or very valuable goats. However, caprine isolates of Mannheimia and Pasteurella are not often resistant to antibiotics routinely used for respiratory disease, as determined by the disk diffusion assay method (Berge et al. 2006). Ventilation should be corrected to decrease humidity in the barn, so that there is no condensation on windows and walls. Nutrition, including vitamin E and selenium, should be optimized. Newly introduced goats should be kept isolated from the herd for at least two weeks. In some outbreaks, young kids appear to be especially susceptible to pasteurellosis in a septicemic or pneumonic form. Colostral transfer of antibodies may be very important in preventing these infections of the neonate (Gourlay and Barber 1960). No bacterin has been proven effective against pasteurellosis in goats. This is partly because of a multitude of serotypes possible (Ward et al. 2002) and partly because the antibodies produced in response to vaccination may contribute to damage of pulmonary tissue when infection occurs. A commercial vaccine containing multiple sheep isolates decreased lung lesions in goats in one small trial (Zamri-Saad et al. 1999). A toxoid vaccine directed against the leukotoxin produced by M. haemolytica, as developed for cattle (Bechtol et al. 1991), may prove more useful but needs further evaluation in goats (du Preez et al. 2000). Recently, M. haemolytica A1 organisms embedded in microagar beads and deposited in lung tissue by the transthoracic (Purdy et al. 1990, 1993) or subcutaneous (Purdy 1996) route have induced significant immunity to challenge exposure in goats. If goats become more popular models for bovine respiratory disease, an effective vaccine may eventually be developed.

Clinical and Necropsy Signs and Diagnosis Because the incubation period is long, this is a chronic pneumonia in adult goats and sheep. Clinical signs of dyspnea, exercise intolerance, and weight loss resemble the signs of progressive interstitial retroviral pneumonia. One to many abscesses may be present in any part of the lung. The abscesses are round, greenish-yellow, encapsulated, and caseo-purulent or caseo-calcified. Radiographic studies help distinguish the pneumonia from the cranioventral, lobar distribution of pasteurellosis. Pleuritis may occur when abscesses rupture into the pleural cavity, but crackles from exudate moving in airways are not routinely auscultated. Histologic examination reveals concentric zones of necrotic neutrophils, round cells (i.e., macrophages, lymphocytes, and occasional giant cells), and fibrosis. Presence of Gram-positive diphtheroid bacteria and absence of acid-fast bacteria help to rule out tuberculosis (Sharma and Dwivedi 1976b). Diagnosis In the absence of external abscesses, diagnosis is difficult without a tracheal wash or necropsy examination. If the goat is in a closed herd that has never experienced contagious abscesses, the probability of caseous lymphadenitis is minimal. Serological test results for the organism (see Chapter 3) in affected goats are usually positive, but this cannot be used to confirm a diagnosis of the pneumonic form of caseous lymphadenitis in a herd in which goats are frequently affected with external abscesses. Positive serologic test results also occur during the incubation period of an external abscess and after its resolution by drainage. Treatment Long-term antibiotic treatment has little effect on the abscesses. A possible exception might be the combination of penicillin or oxytetracycline and rifampin (Chapter 3). Because the condition is most readily confused with the equally untreatable retroviral pneumonia, euthanasia is warranted when other conditions amenable to therapy have been excluded from the differential diagnosis.

Caseous Lymphadenitis Abscesses in the Lungs Corynebacterium pseudotuberculosis abscesses are most commonly found in the head and neck lymph nodes (see Chapter 3), but abscesses may form in the lung parenchyma or mediastinal lymph nodes. In one slaughterhouse study of 25,467 goats in India, pseudotuberculosis lesions were seen primarily in the lungs of eighty-nine (0.349%) goats, and thirty of these animals had similar lesions in bronchial or mediastinal lymph nodes (Sharma and Dwivedi 1976b).

Prevention The pulmonary form of caseous lymphadenitis is reportedly common in infected flocks of sheep that are driven through a dipping vat immediately after shearing. The dipping solution becomes contaminated with pus from open abscesses and is then swallowed or inhaled by other animals in the flock. Angora and Cashmere goats should be at similar risk. Dipping should be postponed until at least two weeks after

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shearing if the disease is present in the flock. Another mode by which infection reaches the lungs is by drainage of the thoracic duct into the systemic circulation. Finally, aerosol transmission from another animal with pulmonary abscesses is possible, although intranasal inoculation failed to produce abscesses in experimental goats (Brown et al. 1985). Thus, culling all goats with external abscesses or chronic wasting is important to preventing pulmonic caseous lymphadenitis. Tuberculosis Contrary to the fervent belief of many hobbyists, goats are susceptible to tuberculosis (Ramirez et al. 2003). Goats may serve as a reservoir of infection for cattle or they may directly infect humans. On the other hand, humans with tuberculosis (especially if immunocompromised by concurrent human immunodeficiency virus infection) are a potential source of tuberculosis infection for goats. Etiology Mycobacterium bovis typically causes pulmonary lesions in goats, whereas M. avium is generally associated with intestinal involvement. Infection of goats seems to occur infrequently, even in regions where cattle and swine tuberculosis is prevalent (Nanda and Singh 1943; Thorel 1984). Mycobacterium tuberculosis (human type) is a rare cause of generalized caprine tuberculosis (Sharma et al. 1985). Recently, some strains of M. tuberculosis isolated from goats, cattle, wildlife, and humans in Europe and having multiple IS6110 insertion sequences have been classified as a new species, M. caprae (Prodinger et al. 2005). These include strains previously identified as M. bovis subsp. caprae or M. tuberculosis subsp. caprae, calling into question the species identification in the earlier literature. Mycobacterium kansasii has been cultured from the mediastinal lymph nodes of one tuberculin positive goat during a tuberculosis eradication effort in the Canary Islands (Acosta et al. 1998). Tubercle bacilli are Gram-positive, acid-fast, and aerobic. Culture is easily done in Dorset or Stonebrinks medium. Primary cultures require three to four weeks before colonies are visible. The organisms are killed by pasteurization but may survive for a long time in moist soil or organic matter. Clinical Signs In countries where tuberculosis still occurs in livestock, pulmonary tuberculosis caused by Mycobacterium caprae and possibly other species may cause severe respiratory signs in goats or remain in a subclinical stage. Weight loss, poor milk production, anemia, and moderate coughing are possible clinical signs (Bernabé et al. 1991) but are nonspecific. Some goats also have firm nodular lesions in the udder.

Diagnosis Diagnosis in living goats is ordinarily made by an intradermal tuberculin test, performed as for cattle. In the United States, only federal, state, and accredited veterinarians may perform a tuberculin test. A 26gauge, 1-cm needle is used to inject 0.1 ml of PPD Bovis tuberculin intradermally in one tail fold. The test result is determined by observation and palpation at seventy-two (±6) hours (USDA 2006). Other countries may require injection of the tuberculin in the cervical skin, and this site is used in the United States for a comparative cervical test where the reaction to M. bovis antigen is compared to the reaction to M. avium antigen. False-positive skin tests may be seen in herds infected with or practicing vaccination against paratuberculosis, because of a potential for mycobacterial cross reactions. Numerous dual infections with the two mycobacterial species have been observed, however, in goats in Spain (Bernabé et al. 1991). An appropriate serologic test may be helpful in confirming a diagnosis of tuberculosis in animals from herds that are also infected with paratuberculosis (Acosta et al. 2000). A bovine gamma interferon test for cell mediated response using bovine PPD was positive in one tuberculin skin test positive goat from which M. bovis was isolated but was also positive in twelve other skin test negative goats which were negative on culture (Cousins et al. 1993). Thus, the gamma interferon test may have poor specificity in exposed but apparently uninfected goats. Various authors report caseation, calcification, and encapsulation of lesions in lymph nodes; in the parenchyma of the lung, liver, and spleen; and in the peritoneal and pleural cavities (Murray et al. 1921; Carmichael 1938; Bernabé et al. 1991). When caseous granulomas are found in the lungs at slaughter or at necropsy, histology (including acid fast stains) and culture are necessary to confirm the diagnosis. Other agents that might cause a similar pneumonia include Yersinia pseudotuberculosis (Rajagopalan and Sankaranarayanan 1944), Burkholderia (Pseudomonas) pseudomallei, Rhodococcus equi (Carrigan et al. 1988), and Corynebacterium pseudotuberculosis. Granulomatous pneumonia caused by the opportunist Cryptococcus neoformans together with M. bovis has been reported in a goat that was negative on intradermal and serologic tests for tuberculosis, suggesting an underlying immunodeficiency (Gutiérrez and García Marin 1999). Control Government regulations concerning herd quarantine and removal of infected animals must be followed. Cleaning and disinfection with Virkon® (Antech International) or a cresol product such as 5% phenol solution should be stressed, with special attention to feed

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troughs and water containers. Other livestock species on the premises and the human caretakers should be tested for tuberculosis. Milk fed to goats and humans should be pasteurized. Melioidosi