Neurological diseases of small animals 3

Question 1

List commo neuroinhibitory toxins

Answer 1

• Venom (not found in UK)
• Macadamia nuts
• Metronidazole

Question 2

What is the first line of treatment with all causes of intoxication?

Answer 2

Decontamination

Question 3

List the methods for decontamination of gastrointestinally absorbed toxins

Answer 3

• Emesis
• Gastric lavage
• Activated charcoal
• Colonic lavage and cathartics

Question 4

Outline the use of emesis as a method of decontamination of toxins

Answer 4

• Within 2 hours of ingestion
• In alert patients only in order to prevent aspiration pneumonia
• LImits absorption

Question 5

Outline the use of gastric lavage as a method of decontamination of toxins

Answer 5

• Within 2 hours of ingestion
• Can be used in subdued/comatose animals
• Must be under GA
• Extreme care to protect airways using cuffed ET tube

Question 6

Outline the use of activated charcoal as a method of decontamination of toxins

Answer 6

• 1-5g/kg every 6-8 hours for up to 24 hours

- In alert patients only

Question 7

Outline the method of decontamination of cutaneous toxins

Answer 7

• Bath, for stable patients

- Washing up liquids may be best as are effective against greasy substances which are absorbed best through the siin

Question 8

What method is used for the decontamination of inhaled toxins?

Answer 8

Ventilation, mechanical in severe cases

Question 9

Outline the use of lipid infusions as a method of decontamination of toxins

Answer 9

• Lipid infusion (intralipid) if exposure to lipophilic substances
• Acts as lipid sink
• Bolus of 2mg/kg followed by CRI of 4mg/kg/hr for 4 hours

Question 10

Describe the clinical signs of ivermectin and macrolide parasiticide toxicity

Answer 10

• Ataxia
• Lethargy
• Tremors
• Mydriasis
• Blindness
• Hypersalication
• Disorientation
• Seizures rare)
• In minority of cases: weakness, stupor, coma, respiratory failure

Question 11

Outline the management of ivermectin and macrolide parasiticide toxicity

Answer 11

• Emesis
• Activated charcoal
• Lipid infusion
• Supportive treatment (temperature)
• Phenobarbital for seizure control or propofol CRI if not responding

Question 12

Discuss the prognosis for ivermectin/macrolide parasiticide toxicities

Answer 12

• Dose related
• Can be guarded
• Long recovery due to long half life (can have significant financial impact)

Question 13

How does metaldehyde intoxication occur?

Answer 13

Found in slug and snail baits, contain beetroot derivatives so smell and taste appealing

Question 14

Describe the mechanism of action of metaldehydes leading to toxicity

Answer 14

• Reduces levels of GABA, reducing inhibition and increasing excitation
• Reduce levels of noradrenaline and serotonin, leading to behavioural effects
• Pro-convulsive effects

Question 15

What are the lethal doses of metaldehyde in cats and dogs?

Answer 15

LD50 100mg/kg in dogs, 207mg/kg in cats PO

- Difficult to know how much ingested as is sprinkled on the ground

Question 16

Describe the clinical signs of metaldehyde toxicity

Answer 16

• Anxiety
• Muscle tremors
• Fasciculations
• Ataxia
• Seizures common
• Minority: tachypnoea, tachycardia, hyperthermia
• Muscle involvement can lead to heat stroke
• Vomiting and diarrhoea with highly indicative green-blue colour
• NB often late presentation

Question 17

Describe the management of metaldehyde toxicity

Answer 17

• Emesis or gastric lavage if not yet seizuring
• Activated charcoal
• Benzodiazepine/phenobarbital for muscle tremors/seizures
• Propofol infusion in refractor seizures
• Monitor body temp, cool if needed

Question 18

Outline the prognosis for metaldehyde toxicity

Answer 18

Good if prompt intervention

Question 19

How does methylxanthine toxicity occur?

Answer 19

Ingestion of caffeine, theobromine (chocolate), theophylline

Question 20

Describe the mechanism of action of methyxanthine toxicity

Answer 20

• Elevation of intracellular cAMP, leading to increased intracellular Ca++ and increased neuromuscular excitability and inotropic effect
• Competitive inhibition of adenosine receptors leading CNS stimulation (A1 and A2 present in brain, regulat heart beat, release of dopamine and glutamate, adenosine increases heart rate and stimulation of the brain)
• Acts on autonomic nervous system

Question 21

What doses of caffeine and theobromine are likely to lead to mild clinical signs and seizures?

Answer 21

• Mild: 20mg/kg
• Seizures: 60mg/kg
• Cocoa percentage on packet can help work out how many mg

Question 22

Describe the clinical signs of methylxanthine toxicity

Answer 22

• Usually 1-2 hours after ingestion
• Restlessness, hyperactivity
• V/D
• Tachycardia/tachypnoea
• Polyuria
• Muscle twitching
• Seizures (tonic or tetanic)
• Hyperthermia

Question 23

Describe the management of methylxanthine toxicity

Answer 23

• Emesis/activated charcoal
• Control of ventricular arrhythmias (lidocaine, procainamide, Ca channel blockers, beta blockers)
• Control muscle tremors/seizures with BZD/phenobarb/propofol if refractory
• Control temperature

Question 24

Outline the prognosis for methylxanthine toxicity

Answer 24

• Dose dependent

- Good if early treatment

Question 25

How does organophosphate and carbamate toxicity occur?

Answer 25

Ingestion or dermal contact, commonly used in agriculture, domestic garden use and external parasite control

Question 26

Describe the mechanism of action of organophosphates and carbamates leading to toxicity

Answer 26

Inhibit action of acetylcholinesterase so Ach accumulates in synaptic space leading to continued muscle contraction (Na+ continues to pass through the channels that are opened by ACh)

Question 27

What are the 3 syndromes of organophosphate/carbamate toxicity?

Answer 27

• Acute
• Intermediate
• Delayed (neuropathy)

Question 28

What are the 4 groups of clinical signs seen in acute OP/carbamate toxicity?

Answer 28

• Muscarinic (autonomic Ach receptors)
• Nicotininc (peripheral NS Ach receptors)
• CNS signs
• Heat stroke as a result of muscular thermogenesis

Question 29

Describe the muscarinic clinical signs of acute OP/carbamate toxicity

Answer 29

• Hypersalivation
• Lacrimation
• Urination
• Defaecation
• Vomiting
• Miosis
• Bradycardia
• Bronchospasm

Question 30

Describe the nicotinic clinical signs of acute OP/carbamate toxicity

Answer 30

• Muscle fasciculations, twitches, tremors

- Dealy neuromusclar signs due to damage to receptors from over stimulation leading to weakness and paralysis

Question 31

Describe the CNS signs of acute OP/carbamate toxicity

Answer 31

• Anxiety
• Ataxia
• seizure
• Obtundation (reduced alertness)
• Coma

Question 32

Describe the intermediate syndrome of OP/carbamate toxicity

Answer 32

• 7-96hours
• Severe neuromuscular signs
• Weakness
• Neck ventroflexion
• Generalised FL weakness
• Hypoventilation (intercostal muscles may be affected)

Question 33

Describe the delayed syndrome of OP/carbamate toxicity

Answer 33

• 1-4 weeks after exposure
• Anorexia, lethargy, pevic limb paresis
• Hyperaesthesia
• Neck ventroflexion (cat)
• Uncommon
• Presents as LMN weakness

Question 34

Describe the diagnosis of OP/carbamate toxicity

Answer 34

• Known exposure
• Whole blood (heparin) cholinesterase activity <20-25% of normal
• Gastric content

Question 35

Describe the management of OP/carbamate toxicity

Answer 35

• Skin decontamination if topical
• EMesis or activated charcoal if ingestion
• Atropine 0.02mg/kg IV for muscarinic signs
• Pralidoxine (2-PAM) 10-20mg/kg SC, IM or IV (care, may worsen clinical signs)
• Supportive care, esp. temperature

Question 36

Outline the prognosis for OP/carbamate toxicity

Answer 36

• Good if patient survives

- Quick intervention at presentation of initial toxicity needed

Question 37

How may permethrin toxicity occur?

Answer 37

• Commonly found in medicated shampoo, spot on flea treatments, flea collars, environmental insecticidal treatments
• Common in cats due to inappropriate flea treatment product use

Question 38

Why are cats more susceptible for permethrin toxicity?

Answer 38

Deficiency in hepatic glucoronidatin

Question 39

Describe the mechanism of action of permethrin toxicity

Answer 39

• Slows opening and closing of voltage sensitive Na+ channels
• Results in prolonged depolarisation

Question 40

Describe the clinical presentation of permethrin toxicity

Answer 40

• 3hrs to 3 days post exposure
• Muscle fasciculations
• Ears twitching
• Tremors
• Ataxia
• Seizures, hyperthermia, hyperaesthesia

Question 41

Describe the management of permethrin toxicity

Answer 41

• Decontamination of skin if dermal exposure (washing up liquid)
• Control temperature (hyperthermia form muscle fasciculations, hypothermia from bath which will extend half life of permethrin)
• BZD, phenobarb for tremors/seizures
• IV lipids to act as lipid sink

Question 42

Outline the prognosis for permethrin toxicity

Answer 42

• Usually good if treatment/decontamination started promptly

- Recovery takes 2-7 days

Question 43

Explain how mycotoxin toxicity occurs

Answer 43

e.g Penitrem A and Roquefortine

Ingestion for mouldy foods e.g. nuts, soft cheese, garbage, compost

Question 44

Outline the mechanism of action of mycotoxins-

Answer 44

Unknown, likely inhibition of glycine function or release in the CNS

Question 45

Describe the clinical signs of mycotoxin toxicity

Answer 45

• 30 min to several hours post ingestion
• Hyperaesthesia
• Restlessness
• Vomiting
• Salivation
• Muscle tremors
• Seizures
• Status epilepticus (dose dependent)
• Heat stroke

Question 46

Describe the diagnosis of mycotoxin toxicity

Answer 46

• History
• Mass spectroscopy
• Chromatography
• Culture of vomitus
• May be able to identify specific mould toxin

Question 47

Describe the management of mycotoxin toxicity

Answer 47

• Emesis, gastric lavage, activated charcoal (for 24 hours to reduce enterohepatic recirculation of the toxin0
• BZD/phenobarb
• GA for refractory tremors
• Supportive care incl, temperature management

Question 48

Describe the prognosis for mycotoxin toxicity

Answer 48

Generally good, improvements in 1 to 5 days

Question 49

Explain how strychnine toxicity may occur

Answer 49

• Used as a pesticidal for small mammals
• Restricted access in EU countries as plant pesticide, becoming less common
• Inhalation or ingestion

Question 50

Describe the mechanism of action of strychnine toxicity

Answer 50

• Blocks action of glycine (inhibitory neurotransmitter)
• Prevents release fo glycine from Renshaw cells in spinal cord
• CNS and LMN lack of glycine causes contraction of muscles

Question 51

Describe the clinical signs of strychnine toxicity

Answer 51

• Onset 10-120 mins from exposure
• Progressive and severe muscle spasm and extensor rigidity (saw horse and risus sardonicus-rictus grin)
• convulsions
• Heat stroke
• Paralysis of diaphragm leading to hypoventilation )(potentially fatal)
• Pain

Question 52

Outline the diagnosis of strychnine toxicity

Answer 52

• History

- Analysis of gastric content, esp. if suspicious of malicious exposure

Question 53

Outline the management of strychine toxicity

Answer 53

• Emesis (not if clinical signs already present)
• Gastric lavage under GA
• Activated charcoal
• Muscle spasm and convulsions must be controlled by BZDs/phenobar/CRU propofol (24-72 hours)
• Mechanical ventilation may be necessary

Question 54

Describe the prognosis for strychnine toxicity

Answer 54

• Fair to good
• Very painful
• Intervene early and small amount ingested then stand a fair chance

Question 55

Describe the mechanism of action of lead toxicity

Answer 55

• Bind to sulfhydryl groups
• Interferes with haem synthesis, leading to RBC fragility, basophilic stippling within erythrocytes
• Neurotoxicity likely linked to interference with action of GABA, capillary damage, neuronal necrosis, inhibition of Ca2+, interference with dopamine uptake

Question 56

Describe the clinical signs of lead toxicity

Answer 56

• Systemic: V+, anorexia, abdo pain, lethargy, PUPD
• Neuro: behavioural changes (may be presented as forebrain disease), ataxia, head pressing, blindness, tremors, polyneuropathy, seizures
• Signs can be intermittent and depend on exposure.amount ingested

Question 57

Outline the diagnosis of lead toxicity

Answer 57

• History
• Presence of nucleated RBC and basophilic stippling
• Blood lead: >0.35ppm, Urine lead >0.75ppm

Question 58

Describe the management of lead toxicity

Answer 58

• Decontamination: emesis, removal of lead fb, magnesium sulphate 200-500mg/kg PO (cathartic, reduces absorption)
• Chelation therapy
• Seizure control with BZD
• Mannitol to reduce ICP

Question 59

Explain why lead toxicity may raise the ICP

Answer 59

Chronic lead exposure can lead to neuronal damage, which leads to oedema, causing elevated ICP

Question 60

Describe the chelation therapies that can be used for lead toxicity

Answer 60

• Succimer 10mg/kg q8hrs for 10 days
• Calcium EDTA 27mg/kg q6hrs SC injection (must be diluted as can cause renal tubular necrosis)
• D-penicillamine 10-15mg/kg/day for 1 week

Question 61

Describe the prognosis for lead toxicity

Answer 61

Variable, generally goo if undergoing chelating therapy

Question 62

Describe the clinical signs of macadamia nut toxicity

Answer 62

• 12-24 hours after ingestion
• Pelvic limb weakness
• Stiffness
• Paresis
• Muscle tremors
• Vomiting
• Hyperthermia

Question 63

Describe the management of macadamia nut toxicity

Answer 63

• Emesis within 2-4 hours
• Supportive care (fluidotherapy, antiemetics, control temp)
• Methocarbacom to reduce muscle tremors

Question 64

Explain how metronidazole toxicity may occur

Answer 64

• Commonly used antibacterial and antiprotozoal

- Some may receive long or repeated courses of emtronidazole

Question 65

Describe the mechanism of action of metronidazole as a neurotoxin

Answer 65

• Not fully understood
• Purkinje cell loss
• Axonal degeneration in vestibular tracts

Question 66

What is the toxic dose of metronidazole?

Answer 66

60mg/kg/day, some individual susceptibility involved and if given for a few months 40mg/kg/day may be enough

Question 67

Describe the clinical presentation of metronidazole toxicity

Answer 67

• Ataxia
• Vestibular signs
• Tremors
• Seizures
• Peripheral neuropathies
• Often present as vetsibulocerebellar (bilateral)
• reluctance to start movement
• Hypermetria
• Usually bright and alert, eating and drinking
• Tetraparetic

Question 68

Describe the management of metronidazole toxicity

Answer 68

• Discontinue metronidazole
• Supportive care relating to motility mostly
• Diazepam 0.2-0.5mg/kg PO for 3 days accelerates recovery (appears to have antagonistic/displacing effect on metronidazole)

Question 69

What would be the most likely differential for a dog presented with short and fast forelimb movement and long and slow hindlimb movement?

Answer 69

CCSM - caudal cervical spondylomyopathy

Question 70

What are the main causes of “Wobbler” in dogs and horses?

Answer 70

• Horses: cervical vertebral malformation

- Dogs: CCSM caudal cervical spondylomyopathy

Question 71

List the differentials for a 5yo FN dog presented with sudden onset cervical pain and low head carriage

Answer 71

• Cervical muscle myositis
• Spondylosis
• Neoplastic e.g. fibrosarc, soft tissue sarc, osteosarc
• SRMA (steroid responsive meningitis arteritis)
• Focal GME
• Trauma
• SRMA most likely

Question 72

Outline your approach to a 5yo FN dog presented with sudden onset cervical pain and low head carriage

Answer 72

• Full systemic exam to rule out systemic disease incl. blood biochem and haematology
• Advanced imaging (MRI)
• CSF tap

Question 73

List your differentials for a 5mo FN dog with one month progressive ataxia, proprioceptive deficits on all limbs, worse on HL, no systemic illness noted and litter mates normal

Answer 73

• Chronic degenerative radiculomyelopathy (unlikely, usually onset 6-9yo)
• Cervical vertebral malformation
• Cataplexy (but no litter mates affected)
• Cervical spondylomyelopathy
• Hypoglycaemia
• Nutritional
• Neoplasm unlikely due to age
• Neospora
• Meningitis
• Toxicity

Question 74

List your differentials for a 3yo dog presented with tetraparesis following traumatic episode at exercise 5 days prior and anaesthesia for radiography. Dull mental state and behaviour, non-ambulatory, tetraplegia, proprioceptive deficiets in all limbs, cervical pain, low tail carriage

Answer 74

• Generalised GME
• Trauma to cervical spine/fracture
• IVDD
• Neoplasia
• Ischaemic episode
• Radiographic positioning exacerbating traumatic lesions/IVDD
• Ischaemic myelopathy

Question 75

Give your most likely lesion localisation and your differentials for a 1yo FN chihuahua presented with sudden onset tetraplegia overnight. Proprioceptive deficits in all limbs, recumbent, cervical pain, reduced visual placing

Answer 75

• Cervical lesion C1-5 (sensation and reflexes present)
• Neoplasia
• Ischaemic myelopathy
• Trauma
• IVDD
• Acute onset focal GME

Question 76

Give your lesion localisation and most likely differentials for a 5yo ME dachsie presented with sudden onset tetraparesis at exercise, ambulatory, ataxia, facial asymmetry, anisocoria (L

Answer 76

• Brainstem lesion (affecting facial nerve which comes out of brainstem)
• Trauma
• Neoplasia
• Peripheral Horner’s with concurrent cervical disease
• Ischaemic episode
• Focal GME
• FCE in the brainstem

Question 77

Give your lesion localisation and most likely differentials for a boxer presented with asymmetric tetraparesis (worse on left), absent proprioception in all 4 limbs, normal mentation, splayed legs, normal reflexes in HL reduced reflexes in thoracic limbs, normal palpebral but no menace response, facial sensation present, nystagmus. Panniculus present, no cervical pain

Answer 77

• C6-T2 lesion
• degenerative myelopathy
• IVDD (less likely, bu chonic protrusions can cause less pain)
• Cervical spondylomyelitis
• Neoplastic
• Discospondylitis
• Most likely are inflammatory, neoplastic and degenerative causes

Question 78

What is chronic pain?

Answer 78

Maladaptive, extends beyond the time for healing

Question 79

Define pain

Answer 79

The conscious recognition of nociceptive stimuli

Question 80

What are the 2 key ascending pathways of pain?

Answer 80

Spinocervicothalamic tract and spinoreticular tract

Question 81

What is the function of the spinocervicothalamic tract in pain? How is it tested?

Answer 81

Touch and superficial pain with high degree of somatotropy, test by light quick pinch of the skin

Question 82

Describe the anatomy of the spinocervicothalamic tract

Answer 82

• Located in lateral funiculus
• Primary afferent synapses with secondary afferent into spinocervicothalamic tract
• Ascend to C1 and C2 where they cross and synapse in lateral cervical nucleus
• Project through brainstem to thalamus and cortex

Question 83

What is the function of the spinoreticular tract?

Answer 83

Deep pain and visceral sensations, poor somatotropy, intersegmental reflexes

Question 84

Describe the anatomy of the spinoreticular tract

Answer 84

• Primary afferents enter cord and diverge cranially and caudally and spreads over several segments
• Second order afferents in dorsal horn (therefore diffuse and bilateral)

Question 85

What activates the emotional response to pain?

Answer 85

The limbic system

Question 86

Explain the gate theory of pain

Answer 86

• CNS can control nociception
• Activity in large non-nociceptive fibres can modify perception of activity in small nociceptive fibres and descending activity can also inhibit it
• Small fibres control large fibre signals in spinal cord

Question 87

Explain the use fo methadone in chronic pain patients

Answer 87

• Pure mu agonist and acts on NMDA receptor and affects serotonin reuptake
• Interferes with sensation of pain as NMDA is wind up receptor in chronic pain

Question 88

List the main medical analgesia options

Answer 88

• Opioids
• NSAIDs
• Alpha-2 agonists
• NMDA receotor antogonists
• Nitrous oxide
• Local anaesthetics
• Paracetamol, steroids, amantidine, tramadol, gabapentin, tapentadol, pregabalin, TCAs, SSRIs, methocarbamol

Question 89

Discuss the use of opioids as analgesics

Answer 89

• ACute pain phase
• Side effects prohibit chronic use
• Tolerance can develop
• May develop opioid induced pain hypersensitivity so pain becomes uncontrollable with chronic use

Question 90

Discuss the use of NSAIDs in analgesia

Answer 90

• Care re. contraindications

- Welfare perspective requires use

Question 91

When are alpha-2 agonists indicated as analgesics?

Answer 91

Peri-operatively only, not suitable for chronic pain treatment

Question 92

Give an example and indication for the use of NMDA receptor agonists as analgesics

Answer 92

• Ketamine

- Chronic pain

Question 93

Discuss the use of nitrous oxide as an analgesic

Answer 93

• Less used now for intraoperative

- Some benefits for chronic pain as well as antidepressant effects

Question 94

Discuss the use of local anaesthetics in analgesia

Answer 94

• Good intra-operatively

- Reduces risk of chronic pain by reducing hypersensitivity

Question 95

Describe the use of liposome encapsulated opioids

Answer 95

• Allows reservoir of drugs to be stored within layers of liposomal membranes
• Drugs released from liposome in a number of ways that may be categorised as either release through passicve efflux or liposome degeneration
• Fewer adverse effects, no risk to in contact people, lower opportunity for abuse if administered by vet

Question 96

Explain the process of release of opioids from liposome encapsulated opioids

Answer 96

• Degradation of liposome structure via lipases present in tissue fluid and uptake by phagocytic cells
• Liposome degradation is affected by lipid composition, physical characteristics, method of manufacture

Question 97

Give examples of novel delivery systems for analgesics

Answer 97

• Polymer gels and buprenorphine SR
• Liposome encapsulated opioids
• Pro-drugs

Question 98

OUtline the holistic approach to the treatment of chronic pain

Answer 98

• Weight control, exercise, physical therapies, acupuncture
• Functional foods, neutraceuticals, DMOADs
• Licensed pharmacotherapy (NSAIDs, PLT, paracetmol)
• Un-licensed pharmacotherapy e.g. amantadine, tramadol, gabapentin, methocarbamol, trazadone

Question 99

What is the main use of amantadine in vet med?

Answer 99

Multimodal analgesic for alleviation of refractory osteoarthritis pain in dogs

Question 100

Identify “other” chronic pain treatments that can be used in vet med

Answer 100

• Stem cells
• Physical therapies
• Complementary therapies
• Nerve growth factor therapies
• EP4 Rc antagonists
• Autoimmune therapies
• Therapies targeting descending controls
• Euthanasia