Injectable Anesthetics

Question 1

GABA Binding Site on GABA A R

Answer 1

btw a1, b2 subunits

Question 2

Benzodiazepines binding site on GABA A R

Answer 2

btw a1, g2

Question 3

Ethanol, inhalants binding site on GABAA

Answer 3

on a subunit

Question 4

Neurosteroids, propofol binding site on GABA A

Answer 4

Beta subunit

Question 5

Barbiturates binding site on GABA A

Answer 5

Beta subunit, separate from neurosteroids or propofol

Question 6

GABA A R - conservation among species?

Answer 6

Where agents work is conserved among species

Question 7

Ideal Injectable Anesthetic Agent

Answer 7

water soluble, long shelf-life, stable when exposed to heat and light, potent, large safety margin, short duration, no cumulative effects, readily metabolized or excreted, adequate analgesia and muscle relaxation, minimal CV/R side effects

Question 8

Basic Structure of Barbiturates

Answer 8

Derivatives of barbituric acid with urea + malonic acid

Barbiturate acid alone has no sedative, hypnotic properties
o Modification of carbon 5 in pyrimidine nucleus gives hypnotic properties

R1, R2 side chains create properties of barbiturates
 Longer side chain: increasess potency, affects DOA

Due to R1/R2 side chain asymmetry at carbon 5, become racemic mixture in solution
 L-isomers 2x potent D-isomers
 All drugs made by modifications of these R1/R2 side chains

Question 9

Thiopental from Oxybarbiturate

Answer 9

o Replace Carbon 2 oxygen with sulfur  thiobarbiturate (thiopental) from oxybarbiturate
 increased lipophilicity = increased potency with faster onset, short DOA

Question 10

Thiobarbiturate

Answer 10

sulfur atom at position 2; thiopental and thiamylal

Question 11

Oxybarbiturate

Answer 11

oxygen at position 2; pentobarb, phenobarb, methohexital

Question 12

MOA Barbiturates - lower doses

Answer 12

enhance GABAA
 decreases rate of GABA dissociation, increases duration Cl channel open
 increases Cl conductance –> hyperpolarization of postsynaptic neuron –> CNS depression, unconsciousness

Question 13

MOA Barbiturates - higher doses

Answer 13

direct activation of channel, mimics GABA
o Inhibits synaptic actions of excitatory glutamate, neuronal (central) nAChR
 Role of effect unknown

Question 14

Ultra-Short Acting Barbiturates

Answer 14

Used for induction: thiopental, thiamylal, methohexital

Question 15

Methohexital

Answer 15

-Shown to cause sz DT substitution at R group
-methyl group at N-1 position, 2x potency vs thiopental
 Powder, 2.5% solution stable in fridge for 6 weeks

Question 16

Thiamylal

Answer 16

ethyl radical in thiopental replaced by allyl radical, no longer available

Question 17

Short Acting

Answer 17

Pentobarbital

Question 18

Pentobarbital

Answer 18

o Pentobarbital (oxybarbiturate) – identical to methohexital but lacks methyl group at N1
 Extensive hepatic metabolism = totally dependent on the liver
 Duration 4-8x longer than thiopental (except in sheep, goats – only lasts 20-30min)
 Low therapeutic index
 Most common euthanasia solution

Question 19

Thiopental

Answer 19

o Highly lipid soluble, high protein binding <65% - binds to albumin
–Highly protein bound – decreased protein binding (other drugs – aspirin, bute) or hypoproteinemia – leads to increased drug effects
o 20-30s induction time, DOA 10-15’

Question 20

Thiopental: redistribution

Answer 20

= principle limiting factor for ax duration following single dose
 Bc so lipophilic, rapid cerebral equilibration –> induction of ax –> rapid re-distribution less perfused areas (skeletal m), ultimately fat
 In general: lipid solubility increases with substitution of sulfur at C2 in barbiturate ring

Question 21

Formulation of Thiopental

Answer 21

powder, reconstitute prior to admin
 Not stable in solution
 pH 10-11: painful on inj
 pKa 7.4: 50% ionized at physiologic pH
* Patient becomes more acidemic, greater non-ionized fraction –> non-ionized form crosses cell membrane –> more potent, increased effectiveness as can better cross lipid cell layer
* Not best induction agent for sick patient
* Alkalemia: ionized form favored, ax effect decreased

Question 22

PK Effects - Thiopental

Answer 22

Vol of distribution ~40mL/kg in sheep (45), dogs, and rabbits (38-90)

Elimination HL REALLY short in rabbits 43’) vs dogs (3h, 182’), sheep (>4hrs, 252’)

Question 23

Thiopental Metabolism

Answer 23

hepatic microsomes/ER of hepatocytes, CYP450 inducer

Prolonged effect if problems with CYP450 system

Significant hepatic dysfunction must be present before prolongation of duration

Question 24

Thiopental Elimination

Answer 24

Renal

Question 25

Thiopental: CNS Effects

Answer 25

• EEG pattern – depressed - α pattern progresses to δ and θ waves – then burst suppression and flat EEG
  -Sdation, hypnosis, ax - dose dependent
• Decreased CBF, ICP - decrease in parallel - CPP not adversely affected bc ICP decrease is greater than MAP
  -55% decrease in CMRO2, dose dependent

Question 26

Barbiturate Neuroprotective Effects

Answer 26

Methohexital assoc with CNS excitation, epileptiform sz – do not use in sz patients

Question 27

Ophtho Effects - barbiturates

Answer 27

Slightly decrease in IOP

Question 28

CV effects - barbiturates

Answer 28

• decreases SV, contractility, BP (vasodilation), PCV (splenic sequestration)
• increase HR, splenic size
• Predisposition to hypothermia from venodilation
• Bigeminy (one regular complex, one abN)
  o Sensitizes heart to catecholamine-induced arrhythmias
  o Arrhythmogenic – classically = bigeminy
  o Can decrease incidence with preoxygenation, ventilation
• Transient: rapid redistribution

Question 29

Respiratory effects - barbiturates

Answer 29

• Depression, +/- apnea – usually larger dose as a bolus
• decreases RR, MV, response to arterial hypoxemia/central response to hypercapnia
• Dogs: bronchoconstriction, decreased mucociliary clearance
• Maintains laryngeal motion

Question 30

Hepatic, renal, GI - barbiturates

Answer 30

• Little to no change in healthy patients, only modest decreases HBF
• increased microsomal enzymes only after 2-7d sustained drug admin
• TP: decreased LES tone in cats
• Slightly decreased RBF, likely DT systemic decrease BP/CO

Question 31

Placental effects - barbiturates

Answer 31

severe depression of puppies, don’t have great fat supplies for redistribution or metabolism
o decreased uterine blood flow
o Placental circulation passes through liver before reaching CNS, decreased overall exposure for most metabolized drugs

Question 32

Analgesic effects barbiturates

Answer 32

• No analgesia
  o At subanesthetic dose, can actually be hyperalgesic

Question 33

Perivascular effect following barbiturate injury

Answer 33

barbiturate slough,” vascular tissue damage,

Very alkali, pH ~10

Aspirate back as much as possible, inject lidocaine locally - flush

Question 34

Glucose effect of barbiturates

Answer 34

Return to anesthetized state after recovery given glucose effect of hepatic microsomal function
o Go back to sleep after bolus of dextrose, plasma concentration of barbiturates s
o Barbiturates selectively inhibit glucose transport by some facilitative glucose transporter isoforms in mammalian cells and across BBB

Question 35

Glucose administration to animals recovering from barbiturate ax

Answer 35

can result in re-anaesthetization
 Glucose slows hepatic enzymes
 Fructose, lactate, pyruvate, glutamate
 Can also see with epi, adrenergic agents

Question 36

Species susceptibility to the barbiturate glucose effect

Answer 36

o Dogs, cats: intermediate
o Goldfish: refractory
o Specific lab animals, exotics VERY sensitive

Question 37

Greyhounds and Barbiturates

Answer 37

 decreased hepatic microsomal enzymes: prolonged recovery, cytochrome P450 2B11
* Also affects metabolism of propofol, alfaxalone
* Unknown whether missing or mutant allele – both have been found
 decreased body fat: decreased redistribution, prolonged recovery
 In general, barbiturates not recommended for sight hounds

Question 38

Barbiturates in horses

Answer 38

3 compartment open model
 HL 1-2min, clearance in horses and ponies ~3.5mL/kg/min
 EL HL in horses 147+/-20 vs ponies 222+/-44min
 Requires significant sedation first
 Do not give guaifenesin/thiopental to horse that has just maximally exercised

Question 39

Barbiturates and ruminants

Answer 39

three compartment open model, short duration DT elimination by hepatic metabolism and uptake into fat
 HL sheep 196+/-64min, VD 1000+/-200mL/kg, clearance 3.5mL/kg/min, time of awakening ~30-40’

Question 40

Barbiturates in Swine

Answer 40

Limited by IV access; dose requirement  by 35% when hypovolemic, does not trigger MH

Question 41

Use of Barbiturates

Answer 41

o Reduce doses with other CNS depressants, hypovolemia, hypoproteinemia, acidemia, uremia
o Rapid induction of ax, 20-30s , DOA 15’ in dogs
o Coadmin with lidocaine can reduce incidence of ventricular arrhythmias (may cause toxicity)

Question 42

Propofol + Barbiturates

Answer 42

o No improvement 1:1 with propofol for induction, recovery times/quality superior than TP alone
 Mixtures <1:1 do not maintain bactericidal properties against Pseudomonas, Staph aureus, E coli, Candida albicans

Question 43

Propofol

Answer 43

• More rapid awakening than with other agents, 1977
• Structure
  o Substituted isopropylphenol (2,6-diisopropylphenol)

Question 44

Propofol MOA

Answer 44

o Enhances GABAA R
 Binds to beta subunit
 decreased GABA dissociation, prolonged channel opening –> hyperpolarization of postsynaptic cell

o Inhibition of NMDA R: decreased excitation from NMDA, not main effect
 Potential role in myoclonus SE

Question 45

PK of Propofol

Answer 45

–Rapid CNS uptake
—97-98% bound to albumin, also erythrocyte membrane
–Redistribution to other tissues – terminates effect
–Hepatic metabolism: glucuronidation, ring hydroxylation to water soluble partially active metabolite that further degraded to inactive metabolites via CYP2B11

Extrahepatic metabolism or extrarenal excretion may occur
 Plasma clearance exceeds hepatic BF, supports extrahepatic metabolism +/- extrarenal clearance

Question 46

Propofol Metabolism in Cats

Answer 46

extrahepatic metabolism demonstrated in pulmonary tissue; hepatic lipidosis doesn’t increase morbidity or mortality
* Don’t do hepatic glucuronidation well, rely on pulmonary

Question 47

Propofol PK - dogs

Answer 47

o Dogs: Vd 17.9L/kg, Vdss 9.7mL/kg
o Greyhounds – smaller volume of distribution – suggesting recovery will be slower
o Dogs >8.5yo = slower clearance rate vs younger dogs
o No accumulation in most species

Question 48

Propofol Metabolism

Answer 48

Hepatic: glucuronidation, ring hydroxylation to water soluble partially active metabolite that further degraded to inactive metabolites via CYP2B11

Question 49

Excretion of propofol

Answer 49

renal, inactive metabolisms +/- exhaled
o Humans: metabolized in lungs, breathed off
 Same recovery time in hepatic cirrhosis patients or liver transplant patients vs normal patients
o Vet med: unknown if similar to humans, or metabolites stored and slowly exhaled

Question 50

Propofol Effects - CNS

Answer 50

 Sedation, hypnosis, ax
 decreased ICP, CMRO2
 Maintains central responses to CO2, CBF autoregulation
* Better in patients that have pathology with intracranial pressure, s to BF
 Anti-convulsant

Question 51

CV Effects - Propofol

Answer 51

–Markedly dose-dependent
–Vasodilation/ decreased ABP, SVR and CO
–decreased Inotropy – Ca mobilization/usage, favoring PNS
–No compensatory HR increase/impaired baroreceptor response
–Sensitizes myocardium to epi-induced arrhythmias
* Not arrhythmogenic on own
–Worse in hypovolemic, elderly, LV dysfunction (DCM) – not able to tolerate decreased CO

Question 52

Why see vasodilation with propofol?

Answer 52

• Decreased SNS activity (decreased PNS as well, but more decrease in sympathetic)
• Increased Ca influx – cardiac, vascular
• Altered Ca mobilization intracellularly – reduces usage
• Inhibition of prostacyclin synthesis
  o Potent VC
• NO stimulation, may be carrier
• Activates K-ATP channels

Question 53

Respiratory effects propofol

Answer 53

 Depression, apnea: dose, administration rate dependent
 Transient cyanosis regularly, esp with rapid injection
 decreased VT/RR (CRI), effects likely to worsen over time
 Blunted ventilatory response to hypercarbia, hypoxemia

Question 54

GI Effects Propofol

Answer 54

Humans –> anti emetic properties
 Not demonstrated in vet med

Question 55

Hepatic/renal effects - propofol

Answer 55

no change in HBF, GFR in face of VD
 Also have extra hepatic metabolism

Question 56

MSK effects - propofol

Answer 56

relaxation, myoclonus, dystonia
 Can give ketamine 0.5-1mg/kg IV
 Give enough time to go away, 1-2min after induction – front limbs > hind limbs

Question 57

Neonatal/Fetal Effects - Propofol

Answer 57

crosses placenta, readily cleared - acceptable for c section

Question 58

Analgesia effects propofol?

Answer 58

None

Question 59

Propofol - extravascular effects?

Answer 59

none, not assoc with tissue necrosis

Question 60

Propofol Infusion Syndrome

Answer 60

o Described in people, rare in animals (1 case report)
 Unknown if propofol itself or propofol metabolism

Assoc with high dose, long duration of propofol CRI

Question 61

Propofol Infusion Syndrome MOA

Answer 61

o Mitochondrial electron transport chain
 Failure of ATP production, metabolic acidosis, cell death
 Can’t produce anything including normal Krebs cycle ATP
 Hyperkalemia
o Myocardial failure, bradycardia, asystole, other arrhythmias, death

Question 62

Propofol in Cats

Answer 62

–Heinz body anemia
Repeat daily dosing: Bandage changes, radiation therapy
–MOA: Oxidative injury to RBCs
–CS: Facial edema, malaise, anorexia, diarrhea potentially by third day, Recovery times increased after second day

Question 63

What do cats develop with frequent/daily propofol administration and why?

Answer 63

Heinz body anemia

o More oxidizable sulfhydryl groups on RBC membrane  Heinz body formation
 Other species clear normally in spleen, liver
 Cats don’t utilize glucuronidation pathway well
o Often depends on cat, how affected by it

Question 64

Propoflow 28 in cats

Answer 64

concern of benzyl alcohol, use for normal dosing
 Avoid as CRI
 Unclear how well metabolize preservative

Question 65

Horses and Propofol

Answer 65

Rapid, smooth induction but potential for unpredictable excitement
o Excitement can be prevented if admin GG 3min prior
o Short duration
o Smooth recovery, esp if xyla+prop
 Good sedative following desflurane for recovery
o Will see myoclonic activity
o CRI: unpredictable, poor analgesia but works as sole agent or with other ax

Question 66

Ruminants and Propofol

Answer 66

rapid, smooth
o Apnea effect during induction/intubation
o Goats: short elimination half life 15mi, large volume of distribution (2.56L/kg), rapid clearance rate (275mL/kg/min)
o Sheep: longer elim HL 26min, decreased VD 1+/-0.5L/kg, decreased clearance 85+/-28mL/kg/min

Question 67

Propofol in Swine

Answer 67

rapid, smooth; does not induce MH
o Apnea effect during induction/intubation

Question 68

Propofol Formulations

Answer 68

1. Emulsions
2. Propoflo 28
3. Lipid-free microemulsion
4. Fospropofol

Question 69

Propofol Emulsion

Answer 69

1% propofol, 10% soybean oil, 2.25% glycerol, 1.2% egg lecithin

Discard vials in 6hr, CRI tubing/syringes in 12hr

Slightly viscous, white substance
pH 6.5-8.5
Stable at room temp, not light sensitive
Highly lipid soluble

Will support bacterial growth – strict aseptic technique needs to be used with multidose vials

Not controlled, inexpensive

Question 70

Propofol Lipid Emulsion and bacterial growth

Answer 70

 Will support bacterial growth – strict aseptic technique needs to be used with multidose vials
* Cats, dogs receiving propofol 3.8x more likely to receive wound infections vs animals that did not receive propofol

Question 71

Propofol 28

Answer 71

preservative: benzyl alcohol
 Dogs

Question 72

Propofol Lipid-Free Microemulsion

Answer 72

 Increases shelf life, decreases pain on injection
 Antimicrobial agents, decreased emulsion instability
 PK, PD similar to lipid formulation in dogs, cats
 Reportedly caused severe pain, complications in dogs
 Horses: 3h CRI = similar CP, biochemical results

Question 73

Fospropofol

Answer 73

prodrug being investigated,
 Water soluble, less painful on injection
 Onset time significantly longer

Question 74

Alfaxalone

Answer 74

Structure: neurosteroid

MOA:
o GABAA R (beta subunit)
o Low doses: increases Cl conductance, hyperpolarization
o High doses: GABA agonist

Question 75

Propofol Pro Tips

Answer 75

o Admin over 60-90s to decrease apnea
o 20-30s to see ax effect once administered
o Duration of unconsciousness 2-8’
o To minimize pain on injection, large vein/catheter, lidocaine prior, dilute in line

Question 76

Alfax Formulations

Answer 76

1. cremophor EL (20% castor oil)
2. Alfaxan
3. Alfax Multidose (28d)

Question 77

cremophor EL (20% castor oil)

Answer 77

 Poorly water soluble
 Combined with alphadolone, formulated in 20%polyexyethylated castor oil vehicle
 Saffan in vet med
 Hyperemia in cats
 Histamine release, anaphylaxis in dogs

Question 78

Alfaxan

Answer 78

cyclodextrin carrier, 2-hydroxypropyl-beta-cyclodextrin
 3-α-hydroxy-5-α-pregnane-11,20-dione) – neuroactive steroid capable of inducing anesthesia; 1% solution in 2-hydroxypropyl-β-cyclodextrin
 Makes steroid water-soluble so can admin variety of routes
 2012 - expensive, controlled
 6hr once opened

Question 79

Alfax Multidose (28d)

Answer 79

= chlorocresol, benzethonium chloride, ethanol
 2018
 Not advised for CRI in cats bc unclear how well can metabolize preservatives

Question 80

Alfax PK dogs

Answer 80

Vd following 2mg/kg = 2.4L/kg, terminal plasma elimination HL (t1/2 ) at same dose 25’, clearance 60+/-13mL/kg

Question 81

Alfax PK Cats

Answer 81

VD following 5mg/kg = 1.8L/kg, t1/2 45’, plasma clearance 25+/-8mL/kg/min

Question 82

Alfax PK Horses

Answer 82

following 1mgkg Vd 1.6+/-0.4L/kg, t1/2 33.4min, plasma clearance 37+/-11mL/kg/min
 Foals: t1/2 23+/-5’, clearance 20+/-6mLkgmin, Vd 0.6+/-0.2L/kg

Question 83

Alfaxalone onset, DOA

Answer 83

• Rapid onset, short DOA
  o Terminal half life 25 min in dogs (45 min in cats)
  o Greyhounds similar to beagles

Question 84

Alfaxalone - metabolism

Answer 84

Hepatic
o Phase I: cytochrome P450 –> 5 metabolites, conserved across species
o Phase II: conjugation-dependent
 Cats: alfaxalone sulfate, glucuronide
 Dogs: alfaxalone glucuronide

Question 85

Elimination of Alfax

Answer 85

renal, biliary, fecal

Question 86

Alfax metabolites - cats

Answer 86

axalone sulfate, glucuronide

Question 87

Alfax metabolites - dogs

Answer 87

Alfax glucuronide

Question 88

Ophthalmic effects - alfax

Answer 88

Increase IOP

Question 89

CNS Effects - alfax

Answer 89

 Unconsciousness, ax
 Decrease CBF, ICP, CMRO2
 Shift in dominant frequency band to δ from β

Question 90

Resp Effects - Alfax

Answer 90

 Heavily dose-depression apnea, depression
 Decreased RR, MV, PaO2
 Increased PaCO2
 Less present to absent at clinically used doses

Question 91

CV Effects - Alfaxalone

Answer 91

 Very heavily dose dependent decreased BP, CO, HR (Increased HR in cats)
* Studied up to 50mg/kg in cats, transient
 decreased BP, increased HR in dogs
* Transient
 Parameters stable at clinical doses +/- increase HR
* <6mg/kg dogs

Question 92

Hepatic, Renal, GI Effects Alfax

Answer 92

No controlled studies, cytochrome p450 metabolism
o Other

Question 93

What molecule is alfax derived from?

Answer 93

Progesterone

Question 94

Other Alfax Effects

Answer 94

 No demonstrated sex-specific metabolism even though derived from progesterone, unlike many other steroid compounds
 No Heinz body anemia assoc
 C sections: improved Apgar scores, overall survivability better at 24hr, 30d

Question 95

Alfax Recovery

Answer 95

o Paddling, myoclonus, trembling
o Generally regarded as smooth
o Horses, donkeys: smooth to absolutely horrific recoveries
Alpacas also reported to have rough recoveries

Question 96

Alfax in Dogs

Answer 96

Can be dosed as CRI, OK to use in young dogs (under 12 weeks were tested)
o No pain on injection, recovery longer than propofol with more adverse events (dysphoria)
o Greyhounds: deficient in hepatic microsomal enzymes (cytochrome P450 2B11) needed to metabolize

Question 97

Alfax in Cats

Answer 97

o CRI doses increased vs dogs, 0.18mgkgmin
o Safe for cats <12wks
o More likely to have trembling, paddling during recovery vs propofol

Question 98

Alfax in Horses

Answer 98

Recovery scores significantly worse with alfaxalone
o Suitable for field ax at 2mg/kg/hr + medetomidine 5mcg/kg/hr

Question 99

Ruminants and Alfax

Answer 99

Mitosis in ruminants, no effect on IOP

Question 100

Swine and Alfax

Answer 100

recumbency, deep sedation, minimal SE
o Volume of injectate limit use to small pigs

Question 101

Alfax Clinical Practice Tips

Answer 101

o Volume limits its use to small patients
o When recovering – leave animal in dark area without handling except for monitoring
o Paddling, twitching, hyperreactivity, and ataxia have been reported
o Can use in exotics and other species
 Responses of sedation, ax tend to be conserved across species
o Repeat dosing not assoc with accumulation in cats
o IM sedation useful, but challenging with volumes

Question 102

Etomidate Structure

Answer 102

o Imidazole derivative: R-(+)-pentylethyl-1H-imidazole-5 carboxylate sulfate
o R(+) isomer = 5x potency of S(-), R(+) produces hypnosis
o Unstable in neutral solution, insoluble in water

Question 103

Etomidate Formulation

Answer 103

 0.2% solution in 35% propylene glycol, pH 6.9, hyperosmolar
 Pain on injection DT propylene glycol
* Use large vein, run into line
 Damage to RBCs, intravascular hemolysis DT high osmolality
* 4640mOsm/L vs plasma 300mOsm/L

Question 104

Etomidate MOA

Answer 104

o Agonist at GABAA R, hypnosis
 Low dose: enhances GABA affinity
 High dose: direct activation

Question 105

PK Etomidate

Answer 105

open three compartment model in cats, people
o Fast onset, short DOA DT redistribution (cats = 30min)
 EL HL 2.9h
 VDss 4.9+/-2.25L/kg
 Clearance 2.5 +/-0.8L/kg/hr
o 75% protein bound to albumin, greater active fraction with hypoproteinemia
o Therapeutic index in rats very large vs thiopental, 26

Question 106

Metabolism of Etomidate

Answer 106

Hydrolysis of ethyl ester side chain by hepatic and plasma esterases – nearly complete
o <3% excreted unchanged in urine

Question 107

Etomidate Excretion

Answer 107

• Water soluble inactive metabolite that is excreted in urine, bile, and feces

Question 108

Etomidate CNS Effects

Answer 108

 decreased CMRO2, ICP, CBF (vasoconstriction)
 Maintains CPP
* CPP maintained because no loss in MAP (previously elevated ICP is reduced ) – may preserve cerebral metabolic state
* No change in cerebral oxygen extraction fraction in dogs with cerebral hypoperfusion
 Caution with seizure history – human study, EEG changes, associated with grand mal seizures

Question 109

CV Effects Etomidate

Answer 109

 Cardiac stability: no changes in HR, SV, CO, or MAP , CVP or CI; baroreceptor function and SNS responses appear intact
 May increase LV afterload (DCM patients)
* Other agents/inhalant may negate effect

Question 110

Resp Effects Etomidate

Answer 110

 Postinduction apnea possible – high dose admin quickly
 decreases VT, increases RR (offsets self)

Question 111

Analgesic effects etomidate?

Answer 111

None

Question 112

Hepatic, GI effects etomidate

Answer 112

no Changes
 Retching, regurgitation, hypersalivation
 Humans: nausea, vomiting

Question 113

Adrenocortical suppression

Answer 113

Etomidate

 Dose dependent inhibition of the conversion of cholesterol to cortisol
 Cortisol synthesis inhibited up to 6h in dogs by blockage of 11-beta-hydroxylase
 Mechanism for increased mortality in humans following anesthesia
 Could be problematic in Addisonian or sick/septic patient
 Not for CRI use

Question 114

Other Etomidate Effects

Answer 114

Myoclonus, trembling: extrapyramidal signs
–Disinhibition of subcortical structures that normally suppress extrapyramidal motor activity
–Can be offset by benzo

Maintains laryngeal reflex

Crosses placenta rapidly: metabolized as fast or faster as dam (sheep)

Question 115

Cats and Etomidate

Answer 115

Decreased spontaneous firing of cortical neurons as well as thalamus and reticular neurons
o Excessive salivation noted, fragility of feline RBC

Question 116

Dogs and Etomidate

Answer 116

vomiting, myoclonus, excitement, hemolysis – still choice for CV instability, increased ICP, cirrhosis

Question 117

Horses and etomidate

Answer 117

Not used clinically

Question 118

Sheep and Etomidate

Answer 118

crosses placenta but doesn’t cause fetal depression (metabolized quickly by the dam), 1mg/kg bolus did not depress CV fxn of ewe or fetus

Question 119

Pigs and Etomidate

Answer 119

No MH triggering

Question 120

Clinical Use Tips for Etomidate

Answer 120

o Dose is affected by ASA status
o Induction within ~30s IV admin
o CV or neuro cases (not seizures)
o Pain injection can be mitigated by an opioid
o Awakening from single dose of etomidate more rapid than after barbiturate admin
o Myoclonus can be mitigated by a benzo
o Maintenance of anesthesia not recommended – adrenocortical suppression, RBC damage
 No accumulation

Question 121

Ketamine

Answer 121

Dissociative anesthesia: dissociation of limbic and thalamocortical systems

Two optical isomers exist, positive S+ isomer produces more intense analgesia, metabolized more rapidly, and has lower incidence of emergence reactions than R- isomer

Question 122

Ketamine Formulation

Answer 122

o Preserved with benzethonium chloride, racemic mixture
o 10% aqueous solution
o pH 3.5-5.5
o Purified S-ketamine available in some countries

Question 123

Ketamine Structure

Answer 123

o Phencyclidine (PCP) derivative
o Racemic mixture: R(-), S(+) isomers
 S isomer = 3-4x more potent, increased analgesia/metabolism
 R isomer = more emergence delirium

Question 124

MOA Ketamine

Answer 124

NMDA antagonist, non-competitive
o PCP binding sites
o Normally excitatory; antagonism = inhibitory
o Other receptor targets = opioid, monoaminergic, VG Ca channels, muscarinic, VG Na channels (H site)
o Some action at μ, δ, κ - clinical relevance to analgesia at relevant doses debatable
o Serotonergic receptors may contribute to analgesia
o Anticholinergic receptors may contribute to dissociative effects (emergency delirium, bronchodilation, sympathomimetic), may also be stimulation of SNS

Question 125

Lipid solubility, protein binding ketamine

Answer 125

• Highly lipid soluble, 50-60% protein bound
  o Fast onset, short DOA
  o Easily crosses BBB
• Peak plasma concentrations occur within 1min IV, 10min following IM

Question 126

Ketamine Metabolism

Answer 126

o Demethylation by microsomal enzymes to norketamine (active metabolite)
 All species
o Norketamine hydroxylated, conjugated to water-solub inactive metabolites for renal excretion
 Exception: cats, directly excrete norketamine – why problematic in UO cats, stay asleep
o Care in animals with significant hepatic and renal dysfunction

Question 127

CNS Effects - ketamine

Answer 127

 Resembles cataleptic state
* Appears away but not responsive to stimuli
 Increases CBF, CMRO2, ICP
* Can attenuate increased ICP with eucapnia, benzos or thiopental

Question 128

Ketamine and Seizures

Answer 128

• Epileptiform EEG but no post ictal period
• Safer to avoid in sz patients
• Does not increase threshold
• Anti-convulsant, neuroprotective

Question 129

Recovery with Ketamine

Answer 129

smooth to violent
* Dogs, pigs: recovery can be erratic, twitching, dysphoric

Emergence delirium, potentially caused by misrepresented auditory and visual stimuli

Question 130

CV Effects: ketamine

Answer 130

 Direct negative inotrope, usually overcome by SNS stim
 SNS outflow increased: increased HR, NE uptake postsynaptically inhibited
 increased SVR, Pulmonary VR, HR, CO, myocardial O2 consumption

Question 131

Resp Effects Ketamine

Answer 131

 No significant depression when solo
 Bronchodilation, decreased airway resistance – attractive for asthma, obstructive airway dz
 Normal ventilatory response to decreased PaO2, increased PaCO2
 Apneustic breathing: prolonged inspiration, inspiratory hold, short expiration (MCQ)
 increased airway secretions, salivation
 Maintain laryngeal, pharyngeal reflexes –> uncoordinated, not protective of airway

Question 132

What is the breathing pattern most commonly assoc with ketamine?

Answer 132

 Apneustic breathing: prolonged inspiration, inspiratory hold, short expiration

Question 133

Analgesia effects of Ketamine

Answer 133

 Occurs at subanesthetic doses DT NMDA R: somatic pain, less clear opioid component
 Helps prevent central sensitization

Question 134

MSK Effects Ketamine

Answer 134

 Rigidity +/- spontaneous movement
 Increased IOP, increased tone extraocular m

Question 135

Hepatic, renal, GI effects - etomidate

Answer 135

no effects

Question 136

Etomidate Fetal/Neonate Effects

Answer 136

 Crosses placenta
 Profound neonatal depression when dam induced with ket+midaz vs other injectables

Question 137

Cats and Ketamine

Answer 137

can spray orally, won’t like bc pH 3-3.5 – will salivate
o Can combine ket + xyla + T/Z

Question 138

Cats and Ketamine

Answer 138

can spray orally, won’t like bc pH 3-3.5 – will salivate
o Can combine ket + xyla + T/Z

Question 139

Bears and ketamine

Answer 139

sudden arousal (with a2), DO NOT USE

Question 140

Ruminants, camelids and ketamine

Answer 140

ketamine stun, different doses/cocktails to achieve different levels of out

Question 141

Equine and ketamine

Answer 141

extensive use, sedate appropriately beforehand
o Induction, bolus top ups, maintenance, CRI

Question 142

Clinical Use Tips - ketamine

Answer 142

o Onset within 10 min of IM
o Duration longer with IM due to higher dose usually given
o Don’t reverse the sedative/tranq before the ketamine has worn off – emergence delirium
o IV admin = ax induction within 45-90s
o Duration of single induction dose ket-diaz, tiletamine-zolaz = 20’
o Ocular, laryngeal, and pharyngeal reflexes may remain intact even if patient is anesthetized

Question 143

Telazol

Answer 143

• Tiletamine (dissociative) + Zolazepam (benzo)
  o More potent, long duration vs ketamine
  o 2-(ethylamino)-2-(2-thienyl)-cyclohexanone hydrochloride

Question 144

Telazol Metabolism

Answer 144

o Cats, ruminants: zolazepam longer = better, slow
o Dogs: tiletamine longer, poor recoveries, rigid
o Swine: smooth

Question 145

Telazol formulations

Answer 145

o Reconstitution variability
o pH 2-3.5

Question 146

Telazol and CV Effects

Answer 146

• Does not sensitize to epinephrine-induced arrhythmias

Question 147

Telazol in horses

Answer 147

incoordination
o Can be used for induction after appropriate sedation

Question 148

NZWR and Telazol

Answer 148

tiletamine = nephrotoxin, other lagomorphs appear okay

Question 149

Tigers (big cats) and Telazol

Answer 149

o Past neurological events, opinion vs evidence
o Delayed recovery, hind limb paresis, hyper-reflexia, seizures, death
o New studies say its ok; old cats it’s the same morbidity as other cocktails

Question 150

Metomidate

Answer 150

o First compound of imidazole class designed as non-barbiturate hypnotic
o Freely soluble in water, aqueous solutions unstable and need to be used within 24hr
o Short duration of action <25min, but prolonged recovery
o CV stability - decreased HR, slight decreased CO
o Stable minute ventilation
o Profound m relaxation, no analgesia
o Violent recovery in horses

Question 151

Magnesium Sulfate

Answer 151

muscle relaxant
o Combined with chloral hydrate – reduces toxicity
o Global CNS depression, resp arrest occurs frequently
o Can be used as euthanasia solution if unconscious
o + chloral hydrate = hastens onset of ax, increases depth, decreases toxicity assoc with CH
 2 parts CH: 1 part MS

Question 152

Chloral Hydrate

Answer 152

o 1,1,1 – trichloro-2,2-dihydroxyethane
o Unknown MOA
o Narrow safety margin
 Dose required to produce ax ~ minimal lethal dose
o Slow onset, requires metabolism to active metabolite = trichloroethanol
o 1869 – distinct odor, volatizes slowly at room temperature
o Likely trichloroethanol interacts with GABAA receptor

Question 153

Effects of chloral hydrate

Answer 153

o Dose-dependent sedation, CV depression
 Lag time in sedation DT formulation of active metabolite
 Difficult to assess degree sedation, depression
o Irritating to stomach, mucous membranes – perivascular injection results in sloughing
o Can have severe resp depression
o Vfib, sudden death reported in recovery

Question 154

Chloralose

Answer 154

o Laboratory animals, non-survival
o Heating glucose and chloral hydrate
o Effects 8-10hr
o Elevated BP, HR, RR
o Slow and marked paddling during recovery – little indication for its use in vet med

Question 155

Urethane

Answer 155

Lab animals, concern for carcinogenesis

Question 156

PIVA

Answer 156

maintenance of GA via combination of inhal, inj agents
o Adequate ax conditions with minimal CV depression as long as required
o decreases neg SE of inhal
o Balanced ax – multimodal to decrease dose of each

Question 157

TIVA

Answer 157

• Total intravenous anesthesia (TIVA): maintenance of GA through inj only
  o Field ax
  o Total injectable anesthesia slightly difference – IM
  o Ensure people safety

Question 158

PK of TIVA/PIVA

Answer 158

o Single IV bolus: higher incidence of AE
o CRI: if don’t do initial IV bolus, will take 4-5 HL to reach steady state
o Why usually combine loading dose + CRI
o Intermittent bolus: rapid up/down, can go into sub-therapeutic range

Question 159

Benefits of TIVA/PIVA

Answer 159

 Limit inhalant to minimize use of VPs, anticholinergics ( risk of arrhythmias)
 Better maintenance of cerebral perfusion pressure/cerebral autoregulation
 Lar par
 Debilitated patients: septic abdomen, hemoabdomen, CV compromise

Question 160

TIVA/PIVA reptiles

Answer 160

don’t have to hyperventilate to maintain ax, only breath 1x Q5min, minimize shunting

Question 161

Context Sensitive half time

Answer 161

time taken for blood plasma concentrations of a drug to decrease by one half after infusion that was maintaining a steady state is stopped

Prolonged infusion of drug, how does that alter the half life of the drug?
* Thiopental: do not use as CRI, HL = 50’ after bolus, doubles after 1hr
* Fentanyl: dramatically increased context-sensitive HL ~2-3hr mark

Avoid: Diazepam, thiopental, prolonged fentanyl (>2-3hr)

Question 162

Goals/Advantages of TIVA/PIVA

Answer 162

o Less CV depression: increased MAP, increased CO, better perfusion
o Avoid catastrophic complications: AKI, GI hypoperfusion/sloughing, death

Question 163

Drawbacks of TIVA/PIVA

Answer 163

o CRIs require IV, IO access
 Pinnapeds (seals, sea lion): very deep jugular v bc dive deep into cold water, do not want significant heat loss
 Can be challenging to get IV in reptiles, likely need IO
 May need multiple IV access points
o Syringe pumps, multiple bags – equipment heavy
 Can calculate drip rate with bags!
o Watch volume of IV fluid admin, compatibility of drugs
 Metoclopramide, blood products do not play well with others

Question 164

MAC reduction of lidocaine CRI in horses, dogs, rabbits, reptiles

Answer 164

~30%

Question 165

Monitoring with TIVA

Answer 165

o No spontaneous movement, no nystagmus, will preserve palpebral
 Eye position depends on drugs used

Question 166

If too light with TIVA…

Answer 166

o Too light: quickened palpebral, increased rapid eye movement (nystagmus), increasedd lacrimation,
increased RR/VT, increased muscle tension (necks of horses), movement
 Quick eyes = quick feet

Question 167

If too deep with TIVA…

Answer 167

absent palpebral, central globe, increased RR/decreased VT (shallow breaths), Cheyne-Stokes breathing
 Specific form of periodic breathing
 Waxing, waning amplitude of flow/VT – deeper breathing, shallower breathing, apnea, reverse
 Characterized by crescendo-decrescendo pattern of resp btw central apnea

Question 168

When use TIVA/PIVA?

Answer 168

o Airway wash +/- need to repeatedly extubate patient during procedure
o Thoracotomies: minimize/ exposure of WAG
o Persistent hypotension despite appropriate fluid therapy, inotropic support
o Persistent hypoxemia
 Pyothorax, severe pulmonary dz
 Hypoxic pulmonary VC: well oxygenated alveolus, capillary bed open but if not getting oxygen, alteration in VG-K channels in alveolar smooth muscle + ca channels  vasoconstriction to shift blood AWAY from poorly oxygenated alveoli
 Humans: HPV blunted by volatile anesthetics
 Not evaluated in veterinary patients
o Maintain CPP
 Inhalants: CPP graph is linear, lose area of autoregulation btw 60-150mmHg
o Avoid hyperventilation
 Reptiles

Question 169

Donkeys

Answer 169

: higher dose of a2 for premed, maintenance

Question 170

Cattle

Answer 170

much more sensitive, use 1/10th xylazine dose, lower concentration xylazine

Question 171

Sheep

Answer 171

pulmonary edema DT activation of PIMS (pulmonary interalveolar macrophages – hypoxemia
 Happens whether clinically hypoxemic or not, do not use

Question 172

GKX

Answer 172

 GG = 5% solution, >5% solun GG: RBC lysis
 Ketamine = 1000mg
 Xylazine = 650mg/L horse, 65mg/L cow
 Titrate to effect, 1L mixture ~60min procedure time
* Not safe for recovery beyond 60min mark

Question 173

MKX

Answer 173

“Triple drip” if can’t get GG
 Midaz 50mg/L
 Ket 1000mg/L
 Xyla 650mg/L
 Titrate to effect, 1L mixture, ~60min procedure time, sedate for recovery period

Question 174

Fent and chickens

Answer 174

o Fent MAC sparing 50mcg/kg/h in chickens
o Propofol evaluated in chickens, swans, penguins

Question 175

Reptiles

Answer 175

o Short procedures done with single IM inj of combo of anesthetics
 Alfax, midaz, +/- hydro, +/- ket
o Wildlife, exotic species – avoid giving one agent
o Inhalants for prolonged periods/sx px has historically required hyperventilation
 Vasodilation/hypotension, d shunting, d ventilatory drive, requires NE/epi
 Does not improve with hyperventilation/hypocapnia!
o TIVA or PIVA with alfax to maintain normocapnia, predictable recovery

Question 176

Drugs to Avoid/Not use for TIVA/PIVA

Answer 176

1. Barbiturates
2. Etomidate

Question 177

Why avoid barbiturates for TIVA/PIVA

Answer 177

prolonged/rough recoveries
 Context sensitive half life: 5x  after short infusions
 Induction only

Question 178

Why avoid etomidate for TIVA/PIVA

Answer 178

 No drug accumulation so seems like it would be great
 Inhibition of 11-betahydroxylase –> adrenocortical suppression (up to 6hr in dogs)
* 11-betahydroxylase converts cortisone to cortisol
 Also avoid propylene glycol