Reptile Medicine PDF
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Uploaded by WittyColumbus
University of Surrey
Marie Kubiak
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Summary
These notes cover various aspects of reptile medicine, including initial consultations, husbandry, clinical examinations, faecal analysis, and treatments for common conditions like pinworms, coccidia, ascarids, and protozoa. It also touches upon blood sampling techniques specific to different reptile types and discusses conditions such as hepatic and renal dysfunction, calcium homeostasis, haematology, and pneumonia. Additional topics covered include treatments for post-hibernation conditions, trauma, and osteomyelitis.
Full Transcript
Reptile Medicine Marie Kubiak BVSc CertAVP(ZM) CertAqV DZooMed MRCVS RCVS Recognised Specialist in Zoo and Wildlife Medicine Initial consultation Ensure familiarity with the species Set aside enough time to carry out a full assessment of husbandry To examine the animal Husbandry Most d...
Reptile Medicine Marie Kubiak BVSc CertAVP(ZM) CertAqV DZooMed MRCVS RCVS Recognised Specialist in Zoo and Wildlife Medicine Initial consultation Ensure familiarity with the species Set aside enough time to carry out a full assessment of husbandry To examine the animal Husbandry Most diseases in reptiles develop in association with husbandry deficiencies Any consultation is a good time to evaluate husbandry and make improvements Optimise recovery Address husbandry before clinical disease results Clinical examination It is important to observe the animal prior to handling Often history taking is prolonged and allows for assessment of demeanour, respiration and responses to stimuli Examination should be no different to any other animal Systematic appraisal and analysis Develop a personal system for examination A checklist can help ensure no points are missed Faecal analysis Performed on every patient where possible Most parasites have a direct life cycle Reptiles are not clean! Debilitated animals are more likely to develop secondary parasitic overgrowth Both a fresh smear and flotation technique should be used It is important to be able to identify common parasites Pinworms Oxyurids common in most reptile species Species specific Rarely significant in low numbers Treat if clinical signs present Weight loss, poor growth, diarrhoea, anorexia Fenbendazole 20mg/kg/d for five doses Beware concurrent disease Avoid ivermectin in all chelonia and in green tree pythons due to associated neurotoxicity Coccidia Isospora amphiboluri common in agamids Pathogenic 30mg/kg TMPS for 5d 10mg/kg toltrazuril (Baycox) for 2 days Ascarids Common in tortoises Pathogenic Impaction, ill thrift and death reported Fenbendazole effective Protozoa Tortoise faeces carry a wide variety of motile protozoa Few are pathogenic Treat only if clinical signs suggest pathology Protozoa in carnivorous species are abnormal flora Metronidazole at 50mg/kg q2d Cryptosporidium Cause of small intestinal epithelial hyperplasia in leopard geckos and some monitor species Gastric hyperplasia in snakes Leads to rapid weight loss Growth reduction and regurgitation uncommon in geckos Regurgitation and gastric dilation common in snakes Asymptomatic dormant state common Diagnosis by organism detection Acid-fast faecal/gastric flush preparations Histopathology Treatment Potentiated sulphonamides slow progression Paromomycin and hyperimmune bovine colostrum have shown experimental promise Not readily available HIBC no benefit in small intestinal infection No reliable therapy Advanced cases should be euthanased In contacts should be considered infected Salmonella Captive reptiles frequently carry Salmonella as part of their GI flora Wild reptiles do not Treatment is not recommended due to potential for inducing antibiotic resistance Good hygiene practice will prevent human infection The HPA has produced a leaflet on this topic Ectoparasites Ophionyssus natricus Seen in snakes and lizards High burdens can lead to anaemia Vector of disease Treatment Fipronil (Frontline) at 2ml/kg Used with care due to toxicity of alcohol-based solvent Ivermectin Do not use with Green tree pythons or near tortoises Pterygosomid mites Unusual in UK reptiles Occasionally seen in imported animals Treated by the same methods Blood sampling Tortoises Jugular vein runs superficially from the tympanum to thoracic inlet Supcarapacial sinus Dorsal tail vein samples are frequently lymphcontaminated Subcarapacial sinus sample collection Dorsal tail vein sample collection Lizards Ventral tail vein Proximal tail contains hemipenes in males Insert needle midline Advance until vertebral contact occurs Withdraw slightly Easy to sample in most species Avoid in geckos and juvenile iguanas Jugular vein Runs along a line drawn from the mandibular ramus to the shoulder Difficult to access blind Ventral abdominal vein Haemostasis is very difficult Snakes Ventral tail vein Palatine vessel Possible in large, anaesthetised snakes Cardiac Visualise heart on ventral body wall Immobilise the heart by placing a thumb proximally Insert needle from caudal aspect Biochemistry Ensure access to good reference values Carpenter Exotic animal formulary Serum or Heparinised plasma suitable Modern machines can run a profile in 0.1ml serum 6-8% blood volume can be collected Equates to 0.6ml per 100g (including haematoma) Less in debilitated animals Hepatic dysfunction Very common syndrome with non-specific symptoms Enzymes (AST, GGT, ALT) non-specific AST elevation with normal CK supports hepatocellular damage Low albumin and uric acid, elevated urea Bile acids most reliable marker Single point measurement Insensitive with focal/mild hepatopathy Imaging may identify hepatomegaly Endoscopic or surgical biopsy is required for definitive diagnosis Renal dysfunction Urinalysis limited as urine is modified in the lower intestine Urinary GGT, NAG and AST indicate renal tissue damage Blood AST non-specific Elevated uric acid can indicate compromise Concurrent urea measurement helps with differentiating renal and pre-renal disease Hypocalcaemia and hyperphosphataemia seen in renal disease (RSHP) Calcium Total calcium is not a reliable marker of calcium homeostasis Ionised calcium much more reliable but requires greater sample volume Phosphate elevation with low ionised calcium consistent with secondary hyperparathyroidism 1,25-Cholecalciferol and PTH levels possible in reptilian species but not commercially available Haematology Nucleated red blood cells preclude standard haematology machine use Manual counts simple to perform in-house PCV WBC Heterophilia and leucocytosis common in infectious pathology Monocytosis in chronic infections Leucopaenia with chronic disease, viral infection, sequestration with focal inflammation or chronic immunosuppression with inappropriate husbandry Blood smear evaluation essential Allows differential count Assessment of morphology E.g. toxic heterophil presence, regenerative erythrocyte response Nutritional Secondary Hyperparathyroidism (Metabolic Bone Disease) Affects all reptiles Calcium metabolism requires several factors: Calcium Vitamin D (dietary or UVB provision) Appropriate heating Renal and hepatic function Husbandry deficiencies are common Calcium homeostasis aims to keep blood calcium within a narrow range Reduced availability leads to hypocalcaemia Parathyroid hormone secretion increases Osteoclast activity increases Blood calcium normalises Bone is demineralised Diagnosis Clinical presentation is characteristic Blood calcium may be normal Blood phosphate is usually elevated Radiographs can grade severity Demineralisation, particularly of extremities Bone remodelling Treatment Correct deficiency Intramuscular calcium gluconate Oral calcium and Vitamin D medication Correct husbandry UVB lighting Supplementation Correct temperatures Apply to all animals in group, not only clinical cases Euthanase cases with permanent mobility or feeding compromise. Post-Hibernation Anorexia Primarily tortoises Causes: Excessive length of hibernation Poor health prior to hibernation Low white cell count Chronic stress Failing to reach POTZ Compromises immunity, favours pathogens Disease or trauma during hibernation Poor husbandry and management When to intervene? Loss of 10% body weight during hibernation Failure to urinate or drink within 4 days Failure to eat within one week Presence of any clinical signs Concurrent runny nose syndrome common Post-Hibernation Anorexia Treatment Correct dehydration Fluid therapy and achieve urination Prior to initiation of feeding Increase blood glucose once hydrated Optimal environmental conditions Appropriate nutrition Treat concurrent disease Improve long-term care and management Oesophagostomy Tube Allows easy feeding Medicating Minimal stress for patient Very simple for owner Inexpensive Long-lasting Vital for PHA Minimising hibernation problems Pre-hibernation health check Visual exam, faecal exam, further tests if indicated Scan females! No harm in missing hibernation if tortoise is sick Discuss hibernation length Preparation of hibernaculum Ensure temperatures are appropriate and stable Monitor throughout hibernation Be prepared to act if problems arise Can all tortoises hibernate? YES NO! Hermann’s tortoise Tunisian tortoise Spur-thighed tortoise Red-eared terrapins Marginated tortoise Box turtles Horsfields tortoise Hingeback tortoises Desert tortoise Leopard tortoise African spurred tortoise Red/Yellow foot tortoise Hibernation Preparation Mimic late autumnal conditions Decrease temperature gradually initially Maintain at consistently low temperatures (<15oC) Decreasing light and UVB exposure Starve for 3-4 weeks No necrotic food in gut Usually tortoises do this themselves Bath regularly to ensure hydration Hibernation Hibernate between 3oC-7oC Too cold: frost can cause blindness and limb damage Frequently seen in ‘free hibernating’ UK tortoises Too warm: energy stores are rapidly used up so tortoises lose weight, dehydrate and accumulate toxins 1% weight loss per month is acceptable Management during hibernation Tortoises can and should be handled and checked Weight check Every two days Signs of activity Urination or significantly disturbed bedding suggests increased temperature and a break in hibernation Early hibernation – ensure temperatures low enough Mid/late hibernation - Stop hibernation Monitor ambient temperature at least once daily Ideal is auto-monitoring, data-storing thermometer Any other signs of illness Predator injury in outbuildings Traditional hibernaculum Fridge method Stable temperatures Easy monitoring Preferable Beware fridges with ice formation! Ending Hibernation Outdoor hibernated tortoises will naturally awake in late spring Prolonged hibernation is the most common factor in posthibernation anorexia Utilisation of all energy stores Lack of time to reaccumulate stores before next hibernation Failure to recover from prolonged dormant state UK tortoises are commonly hibernated for 5-6 months Far longer than in their natural climate 4-12 weeks is recommended Hibernation should never exceed 16 weeks Ending Hibernation Tortoises need temperatures >15oC to kickstart the metabolism Warming should occur over several hours Once responsive movement is seen move to normal enclosure Increase temperatures from 15oC to POTZ over 48hrs Provide 8hrs light with UVB Bathe daily Many tortoises require water to stimulate urination Allow hydration via drinking/bladder absorption Monitor weight, urination, defaecation and appetite until normal Post-Hibernation Exam Discuss hibernation protocol used Check weight Physical examination Assess summer management Intervention as necessary Further tests e.g. blood profile Fluid therapy Pharyngostomy tube placement Specific treatment Runny Nose Syndrome Any tortoise species, often Testudo sp Causes: Viral Mycoplasma Bacterial Fungal Hypovitaminosis A Poor husbandry n Diagnosis Clinical appearance distinctive Identify specific causative factors Chelonian herpes PCR Geochelone/Stigmochelys species and Hermann’s tortoises appear particularly sensitive, many others may act as carriers Mycoplasma PCR Chlamydia serology/PCR Dietary and husbandry assessment Bacterial culture and sensitivity Treatment Antibiotics Secondary infections are often cause of symptoms even with herpes and hypovitaminosis A Nasal flushing Antibiotics Saline F10 Improve husbandry Severe cases will require hospitalisation for assist feeding, fluid therapy, nebulisation and flushing. Pneumonia This may be an extension of RNS in tortoises or stomatitis in snakes Viral, bacterial and fungal agents all reported Radiography especially useful in tortoises Horizontal beam views most rewarding Tracheal wash indicated in all reptiles Cytology Culture PCR Lung biopsy/flush can be carried out endoscopically Treatment Antimicrobial therapy based on microbiology Nebulisation 1:250 F10 Antibiotic solutions Clearing of secretions important in snakes Coupage Encourage activity High humidity Tortoise trauma Common in outdoor tortoises Lawnmowers Children Dogs, foxes and rats All wounds should be considered contaminated Maintain as open wounds initially Soft tissue injuries require protection to granulate Shell Fracture Repair Wet-to Dry Bandages Gauze and saline +/chlorhexidine Short-term to clear infection Long-term use traumatises granulation bed Vacuum assisted closure Constant negative pressure of ~125mmHg Excellent for chronically infected wounds Expensive equipment, not practical in all cases Epoxy resin Cannot be used for contaminated wounds Can hinder shell growth Often used together with screws/wires/plates External fixation Cannot replace deficits Good positioning of fragments usually achieved Platelet Rich Plasma Platelets store and release growth factors and chemotactic molecules involves in haemostasis and cell proliferation Sodium citrate anticoagulant Add calcium gluconate to trigger clot formation and apply as a gel Acts as a barrier and promotes local healing Analgesia Antibiotic therapy Secure loose fragments Sterile dressing changes daily Consider patching large defects once confident the area is not infected Fibreglass or non-heating resin Stomatitis Causative factors vary: Herpes virus related in tortoises Snout trauma in lizards Immunosuppression in snakes ?OPMV-1 involvment Culture, cytology and biopsy can aid specific diagnosis Often broad spectrum antibiotic therapy is initiated Topical treatments can help F10 flushes Silver ointments for open lesions Analgesia necessary Periodontal disease Agamids and chameleons have acrodont teeth These are housed in an exposed section of the jaw bone Teeth are not shed and replaced Soft diet or trauma predispose to gingival inflammation and recession Osteomyelitis eventually results Prevention Feed harder diet (avoid soft fruits) Prevent trauma Treatment Remove plaque Debride necrotic tissue and bone Administer topical and systemic antibiotics Neurological disease in snakes Typically presents as: Loss of righting reflex Stargazing Paresis Tremors Seizures Aggressive behaviour Differential diagnoses Heat or mechanical trauma Metabolic abnormalities Renal/hepatic disease Hypocalcaemia unusual in snakes Toxin exposure Nicotine Insecticides Infectious causes Paramyxovirus (Ferlavirus) Seen in colubrids and elapids Predilection for venomous species May cause respiratory or neurological disease Difficult to diagnose reliably Can have an incubation period of up to 1yr 1/3 positive cases asymptomatic 1/5 grossly normal on post-mortem exam Diagnosis by serology Seroconversion takes 6-8 weeks, demonstrate rising titre PCR on oral and cloacal swabs can be used Lung>intestine>liver>kidney for inclusions on histopath Inclusion Body Disease of Boids Due to infection with arenavirus Pythons highly susceptible and develop acute neurological symptoms Single case report in corn snakes Boas can act as subclinical carriers Serology and PCR available for ante-mortem testing Histopathology IBDB Clinical syndrome not necessarily single pathogen Large eosinophilic protein inclusions, NOT viral particles BCI most commonly diagnosed histopathologically 47% of post-mortem BCI cases were positive 95% of these had detectable hepatic inclusions Other Boinae and Pythoninae less commonly affected Very low clinical incidence in pythons Beware assuming diagnosis with ‘typical’ symptoms Agamid adenovirus 1 Cause of neurological signs, poor growth, immunosuppression and death The virus has been demonstrated in clinically healthy bearded dragons 18.5% PCR +ve for agamid adenovirus 1 Breeding groups should be screened to maintain clean colonies Combined choanal and cloacal swabs for PCR Autotomy Tail autoamputation is a natural defence Rough handling, Acute stress or tail trauma triggers vertebral cleavage Ongoing contractions focus attention on the tail Keep the stump clean but do not apply medication or suture the site House the gecko alone, on paper Feed daily as energy and fluid storage is compromised Within 8 weeks a primitive tail will reform Autoamputation can be used to minimise bleeding for tail amputations Osteomyelitis Requires initial entry wound Skin trauma common Bacterial emboli block smallest capillaries Toes typically affected Other joints may less commonly be involved Swelling and pain results Aspiration and radiography needed for diagnosis Analgesia should be prescribed Broad-spectrum antibiotic therapy pending culture Cytology of joints assists in diagnosis Gout Mycoplasmosis Mycobacteriosis Fungal infections Urolithiasis in bearded dragons Urates are semi-solid waste produced by the kidneys Urates are stored in the rectum and cloaca until they are voided with faeces Infrequent defaecation predisposes to dessication of urates refluxed into the colon The colon absorbs fluid to leave a solid urolith Treatment Uroliths are usually easily flushed by instilling fluid into the cloaca and rectum via a blunt ended tube Prevention Adequate fibre Appropriate temperatures Hydration Calcium and UVB provision Any questions?