Wilson K. Rumbeiha, DVM, PhD, DABT, DABVT, ATS Professor of One Environmental Health Toxicology Dept of Molecular Biosciences School of Veterinary Medicine University of California Davis, CA, USA
Renee Schmid, DVM, DABT, DABVT Senior Veterinary Toxicologist DVM Supervisor Pet Poison Helpline & Safetycall International, PLLC Bloomington, MN, USA
Mary Scollay, DVM Executive Director Racing Medication Testing Consortium Lexington, KY, USA
Arya Sobhakumari, DVM, PhD, ERT, DABT, DABVT Research Scientist – Quality and Applied Science Nestle Purina PetCare 1 Checkerboard Square, 3S St. Louis, MO, USA
Bryan L. Stegelmeier, DVM, PhD, DACVP Research Medical Officer USDA Poisonous Plant Research Laboratory Logan, UT, USA
Ashley Smit, DVM Consulting Veterinarian, Clinical Toxicology Pet Poison Helpline & Safetycall International, PLLC Bloomington, MN, USA
Patricia A. Talcott, MS, DVM, PhD, DABVT Clinical Professor, Dept. of Integrative Physiology and Neuroscience Toxicology Section Head, Washington Animal Disease Diagnostic Laboratory Pullman, WA, USA
Christie Ward, DVM, MVSc, PhD, DACVIM Assistant Clinical Professor College of Veterinary Medicine University of MinnesotaSt. Paul, MN, USA
Katherine D. Watson, DVM, PhD, DACVP Assistant Professor of Anatomic Pathology California Animal Health and Food Safety Laboratory System School of Veterinary Medicine University of California Davis, CA, USA
About the Companion Website
This book is accompanied by a companion website:
www.wiley.com/go/hovda/equine
The Website includes:
Figures from the book
Appendix 3 – Information Resources for Toxicology
Chapter 1 Forensic Investigation of Equine Intoxications
Determining underlying causes for sudden or unexplained equine deaths has significant medicolegal importance. Potentially all horses are at risk, but horses are less commonly intoxicated than other species due to more selective dietary habits, more controlled environments, and more observant owners.
Clues that might point towards an intoxication include sudden death of one or more otherwise healthy horses, recent feed or environmental changes, easy access to chemical storage areas or trash piles, access to areas with potentially toxic plants, or threats of poisoning.
Malicious poisoning does occur due to disputes or in situations in which animals are insured or involved in some form of competition.
Determining the cause and manner of death is critical to substantiating claims and the ultimate liability of insurers.
A systematic and thorough postmortem examination is essential to confirm death caused by toxicant exposure.
Documentation (e.g., use of chain‐of‐custody procedures) of proper sample collection, storage, and laboratory submission is crucial, especially with accidental feed contamination or malicious poisoning suspicions.
Toxicant testing can be targeted (i.e., testing for specific toxicants) or non‐targeted (i.e., looking for unknowns). While non‐targeted testing can identify many toxicants, there is no single comprehensive test for unknowns.
It is important to keep an open mind when investigating the death of any animal and not to be misled by allegations of malicious intent.
Exclusive of plants for which ingestion is associated with sudden death, potential toxicants include strychnine, phosphides, cholinesterase‐inhibiting insecticides (e.g., OPs, carbamates), nicotine, metaldehyde, cyanide, fluoroacetate, illicit drugs (e.g., amphetamines, cocaine, heroin, morphine), metals (e.g., mercury, arsenic, lead, selenium, iron), drugs (e.g., insulin, barbiturates, reserpine, succinylcholine), electrolytes (e.g., potassium, calcium) and vitamins A, D, and E.
Ingestion of toxic plants is a less common cause of malicious poisoning but still a possibility. Exposure to extremely toxic plants (e.g., Taxus spp. [yew], Nerium oleander [oleander], Conium maculatum [poison hemlock], Cicuta spp. [water hemlock]) should be considered, as should zootoxins (e.g., cantharidin).
Signs vary considerably depending on the specific toxicant to which a horse is exposed.
Most malicious intoxications are associated with administration of highly toxic drugs or chemicals intended to kill quickly.
An ideal toxicant used maliciously would cause rapid death, not result in specific postmortem lesions, and be difficult to detect in postmortem tissue or fluid samples. Fortunately, the list of toxicants meeting all three criteria is rather limited.
Most toxicants that result in sudden death impair the central or peripheral nervous systems, cardiovascular system, or respiratory system. Thus, if signs are noted before death, they generally relate to failure of one or more of these systems.
Intoxications can result in more chronic disease and multiple exposures might be required before onset of clinical signs (e.g., ingestion of pyrrolizidine alkaloid‐containing plants).
Depending on the toxicant, there might be evidence of struggle before death, as might occur following central nervous system (CNS) stimulation or respiratory impairment. Alternatively, some toxicant‐induced deaths are associated with no struggle before death, as might occur after administration of a barbiturate or other CNS depressant.
There are many causes of sudden or unexplained death other than toxicants:
Physical causes – trauma, electrocution, lightning strike, suffocation, heat stroke, and gunshot.
Natural or genetic causes – hyperkalemic periodic paralysis, cardiac conductive disturbances, acute myocardial necrosis, cerebral thromboembolism, aortic aneurysm or other vessel rupture, and neoplasia.
Infectious or parasitic causes – acute clostridial diseases, salmonellosis, Tyzzer’s disease, anthrax, equine monocytic ehrlichiosis, foal actinobacillosis, babesiosis, and verminous arteritis.
Metabolic and nutritional causes – hypoglycemia, hypocalcemia, hypomagnesemia, and selenium or vitamin E deficiencies.
