Premedication

Question 1

What are the purposes of premedication (7)?

Answer 1

1. Sedation, analgesia
2. Anesthetic sparing effect
3. Reduction of stress and catecholamine release
4. Reduction of O₂ demand
5. Increased safety for animals and humans
6. Decreasing parasympathetic tone
7. Others–antibiotics, antihistamines

Question 2

What are the drugs of premedication?

Answer 2

• Anticholinergics
• Alpha2 agonists
• Phenothiazines and butyerophenones
• Benzodiazepines
• Opioids
• Antihistamines and antibiotics

Question 3

What do anticholinergics inhibit? Which receptors do they act on (and what do they do)? What are the specific drugs?

Answer 3

• Inhibit the parasympathetic nervous system
• Antagonists on muscarinic acetylcholine receptors
• Atroine; Glycopyrrolate

Question 4

Atropine: 3 aspects

Answer 4

• Lipid soluble (= crosses cell membranes)
• Absorbs well IM, SC, PO
• Crosses BBB and placental barrier
  
  • Important when anesthetizing animal for C section

Question 5

Glycopyrrolate–6 aspects

Answer 5

• Water soluble
• Absorbs slowly IM, SC, PO
• Onset of effect is slower than atropine even IV
• Doesn’t cross the BBB or placental barrier
• Dose: half that of atropine (more potent)
• Advantage over atropine is debated
  
  • Atropine faster in emergency situation

Question 6

What are the indications for anticholinergics?

Answer 6

• Increasing heart rate
  
  • Treatment of opioid induced bradycardia (common problem)
  • Prevention/treatment of reflex bradycardia
    
    • Eye surgery (inc. vagal tone)
  • Young animals and brachycephalic breeds
    
    • Heart and SNS not fully developed
  • Routine use is not recommended
• Decreasing salivation and bronchial secretion
  
  • Smaller amount but thicker mucus is not better
  • Usually only indicated for lab animals

Question 7

Contraindications of anticholinergics?

Answer 7

• Tachycardia
• Hyperthyroidism
  
  • Heart is vulnerable–>tachycardic
• Most heart diseases
  
  • Except when needed for treatment of bradycardia
• Narrow angle glaucoma
  
  • Inhibits drainage of aqueous humor–> acute glaucoma

Question 8

Anticholinergics: cardiovascular side effects

Answer 8

• 2^o AV block, bradycardia, cardiac arrest
• Tachycardia, hypertension
• [SA node: atrial conduction (P wave)]
• [AV node: ventricular conduction (QRS)]
• Anticholinergics easily effect the SA node
  
  • Lots of P waves
• Effect on AV node is weaker and comes later
  
  • AV blocks, bradycardia (vagal tone inc.?)
  • When the AV node finally conducts–>excessive tachycardia

Question 9

Are medetomidine and atropine recommended to give together? Why/why not?

Answer 9

• Not recommended to give together
• Results in vasoconstriction, tachycardia, hypertension
• Measure BP before giving atropine

Question 10

What needs to be considered before treating bradycardia?

Answer 10

• Consider species, age, and diseases of patient
• Is the patient hypotensive?
• Is the ET CO₂ adequate (assuming constant ventilation)?
  
  • Can be a sign of cardiac arrest if ET CO₂ drops suddenly
• Treatment plan:
  
  • Drugs: atropine, naloxone, others
  • Dose? Monitoring? Plan B?

Question 11

What are some other effects of anticholinergics?

Answer 11

• Relaxes lower esophageal sphincter (regurg)
• Mydriasis (may trigger acute glaucoma)
• Bronchodilation (increases airway dead space)
• Dries airway secretions
• Intestinal paralysis (may cause colic in horses)
• CNS toxicity
  
  • Atropine crosses BBB: may cause sedation, coma
  • Treatment with physostigmine (not neostigmine)

Question 12

What about rabbits with anticholinergics?

Answer 12

• 1/3-1/2 of all rabbits have high levels of atropinase enzyme, so atropine is quickly broken down and not effective
• Glycopyrrolate is the preferred anticholinergic

Question 13

What are the general characteristics of alpha₂ agonists?

Answer 13

• Strongest available sedatvies
• Have important cardiovascular side effects
• Myriad of other effects
• Have specific antagonists
• Appropriate use is debated (crashing opinions)
  
  • High caution for low CO (contraindicated in USA)

Question 14

Alpha₂ agonists: mechanism of action

Answer 14

• Competitive agonist of alpha₂ adrenergic receptors
• Location
  
  • CNS–presynaptic membrane (autoreceptor)
  • Post-synaptic membrane (vascular smooth muscle)
  • Extra-synaptic sites (e.g. pancreas, lipocytes, etc.)

Question 15

How do alpha₂ receptors work on the presynaptic membrane? What are the effects?

Answer 15

• Suppression of NE release by negative feedback
• Effects
  
  • Sedation (brain: locus ceruleus)
  • Analgesia (spinal cord: dorsal horn)
  • Reduction sympathetic outflow from the brain
  • Reduction of stress response

Question 16

How/where do alpha₂ receptors work on the postsynaptic membrane?

Answer 16

• Smooth muscle wall of arteries and veins
• Along with alpha₁ receptors
• Both mediate vasoconstriction
• Natural ligands
  
  • NE: from sympathetic nerve endings
  • Epi: from adrenal medulla

Question 17

How/where do alpha2 receptors work on extra synaptic sites?

Answer 17

• Lipocytes: inhibition of lipolysis
• Pancreatic beta cells: inhibition of insuulin release, hyperglycemia
• Natural ligand: Epi
• Interaction with stress response

Question 18

What are the CNS effects of alpha₂ agonists?

Answer 18

• Sedative effect is species-specific
  
  • Strong: dogs, cats, horses, ruminants
  • Weak: pigs
• Some analgesic effect
  
  • Synergistic with opioids
• Muscle relaxation

Question 19

What are the cardiovascular effects of alpha₂ agonists?

Answer 19

• Strong vasoconstriction
• Leads to high SVR and BP
• Reflex bradycardia develops
• Result: low CO and tissue perfusion
• BP may decrease later on (hypotension)
• Common recommendation:
  
  • Don’t use atropine (debated)
  • If necessary, give specific antidote (e.g. atipamezole)

Question 20

Alpha₂ agonists: respiratory effects

Answer 20

• Mild respiratory depression
• RR decreases, but tidal volume increases
• Upper airway resistance increases
  
  • Relaxation of larynx, pharynx, and nares
  • Head dropping in horses: nasal edema
• V/Q mismatch in horses
  
  • Low V/Q resulting in decreased PaO₂
• Bronchoconstriction, V/Q mismatch, lung edema and hypoxemia in ruminants
  
  • May occur with any alpha₂ agonist in any ruminant species
  • Mostly reported with xylazine in sheep (therefore, commonly disrecommended)

Question 21

Alpha₂ agonists: GI effects

Answer 21

• Salivation decreases
• Lower esophageal sphincter tone decreases (not specific for alpha₂ agonists)
• GI motility decreases
• Vomiting may occur
  
  • Not good in animals with respiratory problems
  • Most likely in cats using xylazine

Question 22

What is the specific concern with xylazine in cattle?

Answer 22

May cause uterine contractions and abortion

(Not documented in other species or reported in other alpha₂ agonists)

Question 23

Indications of alpha₂ agonists?

Answer 23

• Sedation of aggressive animals
• Sedation in the ICU
• Sedation to manage post-operative airway obstruction (e.g. after brachycephalic sx)
• Prevention/treatment of seizures (epilepsy)

Question 24

Contraindications of alpha₂ agonists?

Answer 24

• Too young or too old
• Hemodynamic instability
• Severely debilitated patient
• Not suitable for most risk patients

Question 25

What are the available alpha₂ adrenergic agents?

Answer 25

• Agonists
  
  • Xylazine
    
    • Highest effect on alpha₁ but affects other receptors as well
  • Medetomidine
    
    • ‘Cleanest’–most specific to alpha₂
  • Dexmedetomidine
  • Detomidine
  • Romifidine
• Antagonists
  
  • Atipemezole
    
    • Extremely specific for alpha₂
  • Yohimbine
    
    • Acts on serotonin receptors–painful, slow (dogs)
  • Tolazoline
    
    • Many side effects

Question 26

What are some of the characteristics among various alpha₂ agonists?

Answer 26

• Specificity to alpha₁/alpha₂ receptor differ
• Medetomidine >>> detomidine > xylazine
• Most effects are mediated by alpha2 receptors
• The main effects are very similar
• Pharmacokinetics and purchase price may differ

Question 27

What are some of the characteristics among alpha₂ antagonists?

Answer 27

• Alpha₂ receptor specificity
  
  • Atipamezole >>> yohimbine >> tolazoline
• Tolazoline and yohimbine are ‘dirty drugs’ acting on other receptors and may have many side effects
• Suggestion: always use atipamezole to antagonize any alpha₂ agonist
• Always give IM except for emergency (IV)

Question 28

What is the unique xylazine dose for cattle? Do xylazine doses differ from medetomidine? What’s xylazine’s duration?

Answer 28

• Cattle dose = 10% of horse’s dose
• Dose of medetomidine does not differ
• 20-40 min

Question 29

What is detomidine used for? What are routes? Duration?

Answer 29

• Used for large animals
• IM, IV, sublingual
• 90-120 min

Question 30

Romifidine: used for? Route? Duration? What is it preferred for and why?

Answer 30

• Used for horses
• IM, IV
• 45-90 min
• Preferred for standing dental surgery–thought to produce less ataxia than xylazine

Question 31

What is the dosing for medetomidine based on?

Answer 31

• USA–body surface area
• EU–body weight
• Package insert doses are generally very high
• Use in combination and reduce the dose

Question 32

What can you give medetomidine in combination with in dogs?

Answer 32

Combination with opioids and benzodiazepines for premed

Question 33

Dexmedetomidine–what is it?

Answer 33

• Medetomidine is a 50:50 racemic mixture
  
  • Dexmedetomidine is the active optical isomer
• Levomedetomidine is the inactive isomer
• Dexmedetomidine is twice as potent as medetomidine
• Otherwise should have the same effects

Question 34

Phenothiazines–agonists or antagonists? What receptors do they act on?

Answer 34

• Act as antagonist on multiple receptors
  
  • Dopamine
  • Serotonine
  • Alpha₁
  • Histamine

Question 35

Is acepromazine a long or short-acting drug?

Answer 35

• Long acting–depends on dose
  
  • 4-8 hours
  • 48 hrs for liver patients
  • Shorter if given in low dose

Question 36

Phenothiazines–CNS effects

Answer 36

• Actions on dopamine and serotonine receptors
• Weaker sedative effects compared to alpha2 agonists
• No analgesic effect
• Antiemetic effect
• Mild respiratory depression

Question 37

Phenothiazines–CV effects

Answer 37

• Actions on alpha₁ receptors
• Vasodilation and hypotension
  
  • Especially in hypovolemic animals
• May cause death in hypovolemic patients
• Measure blood pressure, give fluids

Question 38

Phenothiazines–other effects

Answer 38

• Antihistaminic
• Anti-arrhythmogenic
• Inhibit platelet function
• Penile prolapses in horses
• Certain older phenothiazines cause seizures (not proven about ace)

Question 39

Indications for phenothiazines?

Answer 39

• Mild sedation for premedication or post OP
• Prevention/treatment of opioid dysphoria
• Prevention of emesis caused by morphine
• Sedation for dogs w/ laryngeal paralysis
• Enhance sedative effect of xylazine in horses

Question 40

Contraindications for phenothiazines?

Answer 40

• Hypovolemia, hemodynamic instability
• Very young or very old patient
• Von-Willebrand disease (Doberman)
• Boxers may be sensitive (bradycardia)–avoid
• Breeding stallions–not recommended

Question 41

Butyrophenones–general

Answer 41

• Similar drug family to phenothiazines
• Drugs: droperidol and azaperone (stresnil)
• Sedative effect is similar to acepromazine
• More likely to cause behavioral side effects
• Less hypotensive and stronger antiemetic than ace
• Less effects on platelets
• Anti-arrhythmogenic, not seizurogenic

Question 42

Benzodiazepines–general

Answer 42

• GABA receptor agonists
• Sedative, anticonvulsant, muscle relaxant effects
• Minimal CV and respiratory effects
• No analgesia
• Can cause major behavior changes

Question 43

Benzodiazepines–specific agonists and antagonists

Answer 43

• Agonists
  
  • Diazepam
  • Midazolam
  • Zolazepam
• Antagonists
  
  • Flumazenil
  • Sarmazenil

Question 44

Benzodiazepines–sedation?

Answer 44

• Species specific effect
• Dogs, cats, horses: Disorientation
  
  • Excitation may occur when used alone
• Better sedation effects in ruminants, camelids, pigs, birds, ferrets
• Rarely used alone

Question 45

Benzodiazepines–indications

Answer 45

• Premedication–combine with:
  
  • Opioids
  • Alpha₂ agonists
  • Both
• Induction–combine with
  
  • Dissociative anesthetics (ketamine)
  • Barbiturates or propofol
• Treatment of seizures (status epilepticus)

Question 46

Diazepam–general

Answer 46

• Lipid soluble
• Formulated in propylene glycol or lipid emulsion
• Chemical compatibility is limited
• Give slowly IV
• Poor absorption and pain IM
• Metabolized in liver and duration of action is 1-4 hrs

Question 47

Midazolam–general

Answer 47

• Water soluble (no propylene glycol)
• Good chemical compatibility
• More potent than diazepam
• Shorter acting than diazepam
• Metabolized in liver, but metabolites are inactive (unlike diazepam)
  
  • Diazepam should be avoided in liver patients
• Can be given IM, IV, or via mucus membranes
• Better choice than diazepam

Question 48

Opioids–general

Answer 48

• Exogenous substances that bind to opioid receptors and activate them
• Strongest available system analgesics
• Best choice for treatment of acute pain (e.g. surgery)
• Decreases the dose of anesthetics
• Minimal CV side effects
• Suitable for most risk patients
• Not as effective for chronic pain

Question 49

Opioid receptors (strength, location)

Answer 49

• μ: Strong analgesia, resp. depression, dependency
• κ: Weaker analgesia
• δ: Weaker analgesia (human relevance)
• Location
  
  • Brain
  • Spinal cord (dorsal horn)
  • Peripheral nerves
  • Inflamed organs (e.g. arthritis)

Question 50

What are the classifications of opioids?

Answer 50

• Full agonists–activate receptors and trigger full tissue response
• Partial agonists–activate receptors but do not trigger full tissue response even at highest doses
• Antagonists–bind to receptors but do not activate them

Question 51

What do the following tell you?

Potency

Efficacy

Pharmacokinetics

Answer 51

• Potency–tells you the dose
• Efficacy–tells you the strength of the effect
• Pharmacokinetics–onset, duration of effect, strategy, etc.

Question 52

Opioids–CNS effects

Answer 52

• Analgesia
  
  • Excellent for acute pain
  • Less effective for chronic pain
• Decreasing the MAC of inhalants
  
  • Species dependent
  • Primates > dogs > cats > pigs > horses
  • May increase the MAC in horses
• Sedation depends on
  
  • Species–primates and dogs sedate better
  • Pain level–stronger if there was pain
• Excitation, dysphoria
  
  • Cats may become excited
  • Horses after high dose
• Tolerance
• Dependence

Question 53

Opioids–vomiting

Answer 53

• May trigger or may inhibit vomiting
• Stimulate chemoreceptor trigger zone outside the BBB and may trigger vomiting
• After entering the brain they inhibit the vomiting center
• Water-soluble opioids (morphine) enter the brain slowly–> cause more vomiting
• Lipid-soluble opioids (e.g. fentanyl) enter the brain fast–> vomiting does not occur

Question 54

Opioids–CV effects

Answer 54

• No direct negative inotropy or vasodilation
• Indirectly may reduce sympathetic outflow from the brain (–>reduce BP)
• Increase parasympathetic tone and may cause bradycardia
  
  • Treatable with atropine
• Suitable for most risk patients
• Improves CV function by allowing to reduce the dose of anesthetics

Question 55

Opioids: respiratory effects

Answer 55

• May depress respiration but not as strongly as in humans and primates
• Healthy small animals tolerate high doses well
• Be careful with combinations and sick patients
• Opioids have antitussive effect–therapy
• May inhibit airway protective reflexes (e.g. coughing)

Question 56

Opioids–GI effects

Answer 56

• Nausea, vomiting
• Defecation
• Obstipation
• Spasm of sphincter of Oddi (hepatopancreatic sphincter)

Question 57

Other effects of opioids?

Answer 57

• Hypothermia
• Post-OP hyperthermia (cats)
• Myosis (dogs), mydriasis (cats)
• Inhibition of urination
• Noise sensitivity

Question 58

Indications for opioids?

Answer 58

• Premedication–alone or in combination with
  
  • Benzodiazepines
  • Benzodiazepines and ketamine (cats, small dogs)
  • Acepromazine
  • Alpha₂ agonists (xylazine, medetomidine)
• Perioperative analgesia
• Treatment of acute and chronic pain

Question 59

Opioids–administration (lots)

Answer 59

• IM, SC
• IV boluses or CRI
• PO (e.g. tramadol)
• PCA–patient controlled anesthesia (human)
• Epidural or spinal
• Transdermal (fentanyl patch)
• Transdermal fentanyl solution (Recuvyra)
• Oral mucosa (buprenorphine for cats)

Question 60

Morphine–all the things

Answer 60

• Cheap and strong analgesic; water soluble
• Slow onset (30-45 min), long duration (4-6 hrs)
• High individual variability in elimination
• Metabolized in the liver to an active metabolite
• Elimination is slow in liver and renal patients
• May cause histamine release, especially after high IV doses
  
  • Not good
• Duration of epidural analgesia is 12-24 hrs (need to control bladder)

Question 61

Hydromorphone, oxymorphone

Answer 61

• Strong analgesics (full μ agonists)
• Duration ~4 hrs
• Reliable metabolism
• No histamine release
• Better choices than morphine

Question 62

Methadone

Answer 62

• Similar properties to hydromorphone
• But also acts as NMDA antagonist (another mechanism of analgesia)

Question 63

Fentanyl

Answer 63

• Strong analgesic (full μ agonist)
• Fast onset short duration (15-20 min)
• No histamine release
• May accumulate after long infusions
• Bolus dose for small animals: 2-5 μg/kg IV
• CRI dose
  
  • May be mixed with ketamine

Question 64

Remifentanil

Answer 64

• Similarly potent to fentanyl
• Very short acting (5 min) and does not cumulate, ideal for CRI
• Metabolized by non-specific esterases in muscles and intestines
• Caution: accidental interruption of administration may trigger strong pain
• Boluses may cause sudden bradycardia

Question 65

Butorphanol

Answer 65

• Antagonist on μ and agonist on κ receptors
• Weak and short acting analgesic
• May worsen pain sensation in case of strong pain
• May be used for premedication in combination with benzodiazepines or alpha₂ agonists if there is no strong pain (e.g. radiology)
• May partially antagonize full μ agonists

Question 66

Buprenorphine

Answer 66

• Partial μ agonist
• Stronger analgesic than butorphanol
• Relatively long-acting: 6-8 hrs
• Onset is slow (20-40 min IV)
• Often given to cats because may cause less excitement than full μ agonists
• Cat owners may continue giving via oral mucosa

Question 67

Tramadol

Answer 67

• Weak analgesic
• Metabolites in the liver
• Metabolite is μ opioid agonist (?)
• Tramadol itself inhibits NE and serotonin reuptake (analgesia)
• Not scheduled drug
• Can be given PO

Question 68

Opioid antagonists (2)

Answer 68

• Naloxone–30 min duration
  
  • May be used in small animals to reverse respiratory depression
  • Routine use is not recommended (reverses analgesia)
• Naltrexone–long acting (~10 hrs)
  
  • Antagonize wild animals after long-acting opioids (e.g. carfentanyl or etorphine)

Question 69

Antibiotics

Answer 69

• Cefazolin
• Amoxicillin clavulic acid
• Give IV 20 min before surgery
• Repeat every 90-120 min
• For prevention: give at least 4 hrs before

Question 70

Antihistamines

Answer 70

• H1 antagonist–Diphenhydramine
  
  • Antagonizes the CV effects of histamine in case of an anaphylactic reaction or histamine release
• H2 antagonist–ranitidine, famotidine, cimetidine
  
  • Increase the pH of the stomach (GI protection)
• Both can be given for premedication before mast cell tumor removal