Induction

Question 1

Routine induction vs RSI

Answer 1

• routine induction is the standard in general anesthesia, however a RSI is indicated in patients at risk of regurgitation/aspiration (see Aspiration, A5)
• RSI uses pre-determined doses of induction drugs given in rapid succession to minimize the time patient is at risk for aspiration (i.e. from the time when they are asleep without an ETT until the time when the ETT is in and the cuff inflated)

Question 2

Transfusion infection risks for HIV, Hep C, Hep B, HTLV, Symptomatic bacterial sepsis, West Nile virus per 1 unit pRBCs

Answer 2

HIV 1 in 21 million

Hep C 1 in 13 million

Hep B 1 in 7.5 million

HTLV 1 in 1-1.3 million

Sepsis 1 in 40 000 from platelets and 1 in 250 000 from RBC

WNV no cases since 2003

Question 3

Equipment preparation routine vs RSI

Answer 3

Same

Check equipment, drugs, suction, and monitors; prepare an alternative laryngoscope blade and a second ETT tube one size smaller, suction on

Question 4

pre-oxygenation/denitrogenation routine vs rsi

Answer 4

same

100% O2 for 3 mins or 4-8 vital capacity breaths

Question 5

pre-treatment agents routine vs rsi

Answer 5

routine - Use agent of choice to blunt physiologic responses to airway manipulation 3 min prior to laryngoscopy

rsi - same but can skip this step in an emergent situation

Question 6

Induction agents routine vs rsi

Answer 6

routine - use iv or inhalation induction agent of choice

rsi - use pre-determined dose of fast acting induction agent of choice

Question 7

muscle relaxants routine vs rsi

Answer 7

routine - choice given after onset of induction agent

rsi - pre-determined dose of fast acting (ex. SCh) given IMMEDIATELY after induction agent

Question 8

Ventilation routine vs RSI

Answer 8

Routine - bag mask ventilation

rsi - DO NOT bag ventilate - can increase risk of aspiration

Question 9

cricoid pressure routine vs rsi

Answer 9

routien - posterior pressure on thyroid cartilage to improve view of vocal cords as indicated

rsi - Sellick maneuver, also known as cricoid pressure, to prevent regurgitation and assist in visualization (2 kg pressure with drowsiness, 3 kg with loss of consciousness)

Question 10

Intubation routine vs rsi

Answer 10

routine - Intubate, inflate cuff, confirm ETT position

rsi - Intubate once paralyzed (~45 s after SCh given), inflate cuff, confirm ETT position; cricoid pressure maintained until ETT cuff inflated and placement confirmed

Question 11

Secure machines routine vs rsi

Answer 11

same

secure ETT, and begin manual/machine ventilation

Question 12

order of induction

Answer 12

1. equipment preparation
2. pre-oxygenation/denitrogenation
3. pre-treatment agents
4. induction agents
5. muscle relaxants
6. ventilation
7. cricoid pressure
8. intubation
9. secure machines

Question 13

Solubility of volatile anesthetics in blood from least to most soluble

Answer 13

Nitrous oxide < desflurane < sevoflurane < isoflurane < halothane

Question 14

What are intravenous induction agents, their purpose and examples

Answer 14

• IV induction agents are non-opioid drugs used to provide hypnosis, amnesia and blunt reflexes
• these are initially used to draw the patient into the maintenance phase of general anesthesia rapidly, smoothly and with minimal adverse effects

■ examples include propofol, sodium thiopental (not available in North America), or ketamine

■ a continuous propofol infusion may also be used for the maintenance phase of GA

Question 15

Propofol (Diprivan) class, action, indications, caution, dosing, special considerations

Answer 15

class - alkylphenol (hypnotic)

action - Inhibitory at GABA synapse Decreased cerebral metabolic rate and blood flow, decreased ICP, decreased SVR, decreased BP, and decreased SV

indications - Induction Maintenance Total intravenous anesthesia (TIVA)

caution - Patients who cannot tolerate sudden decreased BP (e.g fixed cardiac output or shock)

dosing - IV induction: 2.5-3.0 mg/kg (less with opioids) Unconscious <1 min Lasts 4-6 min t1/2 = 55 min Decreased postoperative sedation, recovery time, N/V

special considerations - 0-30% decreased BP due to vasodilation Reduce burning at IV site by mixing with lidocaine

Question 16

Ketamine (Ketalar, Ketaject) class, action, indications, caution, dosing, special considerations

Answer 16

class - Phencyclidine (PCP) derivative – dissociative

action - May act on NMDA (antagonistically), opiate, and other receptors Increased HR, increased BP, increased SVR, increased coronary flow, increased myocardial O2 uptake CNS and respiratory depression, bronchial smooth muscle relaxation

indications - Major trauma, hypovolemia, obstetric bleeding, severe asthma because sympathomimetic

caution - Ketamine allergy TCA medication (interaction causes HTN and dysrhythmias) History of psychosis Patients who cannot tolerate HTN (e.g. CHF, increased ICP, aneurysm)

dosing - IV induction 1-2 mg/kg Dissociation in 15 s, analgesia amnesia, and unconsciousness in 45-60 s Unconscious for 10-15 min, analgesia for 40 min, amnesia for 1-2 h t1/2 = ~3 h

special considerations - high incidence of emergence reactions (vivid dreaming, out-ofbody sensation, illusions) Pretreat with glycopyrrolate to decrease salivation

Question 17

Benzodiazepines (midazolam [Vesed], diazepam [Valium], lorazepam [Ativan]) class, action, indications, caution, dosing, special considerations

Answer 17

Class - benzodiazepines (anxiolytic)

action - Inhibitory at GABA synapse Produces antianxiety and skeletal muscle relaxant effects Minimal cardiac depression

indications - Used for sedation, amnesia, and anxiolysis

caution - Marked respiratory depression

dosing - Onset less than 5 min if given IV Duration of action long but variable/somewhat unpredictable

special considerations - Antagonist: flumazenil (Anexate®) competitive inhibitor, 0.2 mg IV over 15 s, repeat with 0.1 mg/mn (max of 2 mg), t1/2 of 60 min Midazolam also has amnestic (antegrade) effect and decreased risk of thrombophlebitis

Question 18

Etomidate class, action, indications, caution, dosing, special considerations

Answer 18

Class - imadazole derivative (hypnotic)

action - Decreases concentration of GABA required to activate receptor CNS depression Minimal cardiac or respiratory depression

indications - induction Poor cardiac function, severe valve lesions, uncontrolled hypertension

caution - Post-operative nausea and vomiting Venous irritation

dosing - IV induction 0.3 mg/kg Onset 30-60 seconds Lasts 4-8 minutes

special considerations - Adrenal suppression after first dose, cannot repeat dose or use as infusion Myoclonic movements during induction

Question 19

Physiology of the neuromuscular junction

Answer 19

1. action potential arrives
2. release of ach into cleft
3. ach binds to ach receptor, ion channels open
4. change in membrane permeability
5. achE hydrolyzes ach
6. action potential spreads across muscle membrane

Question 20

Type of muscle relaxants

Answer 20

1. depolarizing (non-competitive) (succinylcholine SCh)

2. non depolarizing (rocuronium, mivicurium, vecuronium, cistarcurium, pancuronium)

Question 21

Muscle relaxants mechanism

Answer 21

Block nicotinic cholinergic receptors in nmj

Question 22

What muscles do muscle relaxants affect

Answer 22

provides skeletal muscle paralysis, including the diaphragm, but spares involuntary muscles such as the heart and smooth muscle

never use muscle relaxants without adequate preparation and equipment to maintain airway and ventilation

Question 23

muscle relaxation produces which desired effects

Answer 23

1. facilitates intubation
2. assists with mechanical ventilation
3. prevents muscle stretch reflex and decreases muscle tone
4. allows access to the surgical field (intracavitary surgery)

Question 24

how to assess degree of nerve block intraoperatively

Answer 24

nerve stimulator (i.e. train of four) is used intraoperatively to assess the degree of nerve block; no twitch response seen with complete neuromuscular blockade

Question 25

What is plasma cholinesterase and what does it do

Answer 25

Plasma cholinesterase is produced by the liver and metabolizes SCh, ester local anesthetics, and mivacurium.

Question 26

a prolonged duration of blockade by sch occurs with

Answer 26

(a) decreased quantity of plasma cholinesterase, e.g. liver disease, pregnancy, malignancy, malnutrition collagen vascular disease, hypothyroidism
(b) abnormal quality of plasma cholinesterase, e.g. normal levels but impaired activity of enzymes, genetically inherited

Question 27

Depolarizing muscle relaxants moa

Answer 27

Action
Mimics ACh and binds to ACh receptors causing prolonged depolarization; initial fasciculation may be seen, followed by temporary paralysis secondary to blocked ACh receptors by SCh

Question 28

Depolarizing muscle relaxants intubating dose

Answer 28

1-1.5 mg/kg

Question 29

Depolarizing muscle relaxants onset

Answer 29

30-60 s – rapid (fastest of all muscle relaxants)

Question 30

Depolarizing muscle relaxants duration

Answer 30

3-5 min – short (no reversing agent for SCh)

Question 31

Depolarizing muscle relaxants metabolism

Answer 31

SCh is hydrolyzed by plasma cholinesterase (pseudocholinesterase), found only in plasma and not at the NMJ

Question 32

Depolarizing muscle relaxants indications

Answer 32

Assist intubation

Increased risk of aspiration (need rapid paralysis and airway control (e.g. full stomach), hiatus hernia, obesity, pregnancy, trauma)

Short procedures

Electroconvulsive therapy (ECT)

Laryngospasm

Question 33

Depolarizing muscle relaxants side effects

Answer 33

1. SCh also stimulates muscarinic cholinergic autonomic receptors (in addition to nicotinic receptors; may cause bradycardia, dysrhythmias, sinus arrest, increased secretions of salivary glands (especially in children)
2. Hyperkalemia Disruption of motor nerve activity causes proliferation of extrajunctional (outside NMJ) cholinergic receptors Depolarization of an increased number of receptors by SCh may lead to massive release of potassium out of muscle cells Patients at risk 3rd degree burns 24 h-6 mo after injury Traumatic paralysis or neuromuscular diseases (e.g. muscular dystrophy) Severe intra-abdominal infections Severe closed head injury Upper motor neuron lesions
3. Can trigger MH (see Malignant Hyperthermia, A28)
4. Increased ICP/intraocular pressure/intragastric pressure (no increased risk of aspiration if competent lower esophageal sphincter)
5. Fasciculations, post-operative myalgia – may be minimized if small dose of non-depolarizing agent given before SCh administration

Question 34

Depolarizing muscle relaxants contraindications

Answer 34

Absolute - Known hypersensitivity or allergy, positive history of malignant hyperthermia, myotonia (m congenita, m. dystrophica, paramyotonia congenital), high risk for hyperkalemic response

Relative - Known history of plasma cholinesterase deficiency, myasthenia gravis, myasthenic syndrome, familial periodic paralysis, open eye injury

Question 35

Non-depolarizing muscle relaxants MOA

Answer 35

competitive blockade of postsynaptic ACh receptors preventing depolarization

Question 36

Non-depolarizing muscle relaxants indications

Answer 36

Assist intubation, assist mechanical ventilation in some ICU patients, reduce fasciculations and post-operative myalgias secondary to SCh

Question 37

Muscle relaxant reversing agents

Answer 37

• sugammadex is a selective relaxant binding agent
• neostigmine, pyridostigmine, edrophonium are acetylcholinesterase inhibitors
• administer reversal agents when there has been some recovery of blockade (ie. muscle twitch)
• can only reverse the effect of non-depolarizing muscle relaxants
• anticholinergic agents (e.g. atropine, gylcopyrrolate) are simultaneously administered to minimize muscarinic effect of reversal agents (i.e. bradycardia, salivation, increased peristalsis and bronchoconstriction)

Question 38

Reversal agents for non-depolarizing relaxants mechanism of action

Answer 38

Pyridostigmine, neostigmine, edrophonium - (acetylcholineste ase inhibitors) Inhibits enzymatic degradation of ACh, increases ACh at nicotinic and muscarinic receptors, displaces non-depolarizing muscle relaxants Muscarinic effects of reversing agents include unwanted bradycardia, salivation, and increased bowel peristalsis*

Sugammadex - encapsulates and inactivates rocuronium and vecurionium, which decreases amount of agent available to bind to receptors in NMJ

Question 39

Onset of pyridostigmine

Answer 39

slow

Question 40

onset of neostigmine

Answer 40

intermediate

Question 41

onset of edrophonium

Answer 41

intermediate

Question 42

onset of sugammadex

Answer 42

fast

Question 43

Recommended anticholinergic with pyridostigmine

Answer 43

glycopyrolate

Question 44

Recommended anticholinergic with neostigmine

Answer 44

glycopyrolate

Question 45

Recommended anticholinergic with edrophonium

Answer 45

atropine

Question 46

Recommended anticholinergic with sugammadex

Answer 46

N/A

Question 47

General anesthesia maintenance using what

Answer 47

volatile inhalation agents and/or IV agents (ie propofol infusion)

Question 48

Extubation criteria

Answer 48

criteria: patient must no longer have intubation requirements

■ patency: airway must be patent

■ protection: airway reflexes intact

■ patient must be oxygenating and ventilating spontaneously

Question 49

Extubation general guidelines

Answer 49

• general guidelines

■ ensure patient has normal neuromuscular function (peripheral nerve stimulator monitoring) and hemodynamic status

■ ensure patient is breathing spontaneously with adequate rate and tidal volume

■ allow ventilation (spontaneous or controlled) with 100% O2 for 3-5 min

■ suction secretions from pharynx, deflate cuff, remove ETT on inspiration (vocal cords abducted)

■ ensure patient is breathing adequately after extubation

■ ensure face mask for O2 delivery available

■ proper positioning of patient during transfer to recovery room (supine, head elevated)

Question 50

Complications of extubation

Answer 50

• early extubation: aspiration, laryngospasm

* late extubation: transient vocal cord incompetence, edema (glottic, subglottic), pharyngitis, tracheitis

Question 51

What is laryngospasm

Answer 51

• defined as forceful involuntary spasm of laryngeal muscles caused by stimulation of superior laryngeal nerve (by oropharyngeal secretions, blood, extubation)
• causes partial or total airway obstruction

Question 52

in who is laryngospasm more likely to occur

Answer 52

more likely to occur in semi-conscious patients

Question 53

laryngospasm prevention

Answer 53

extubate while patient is still deeply under anesthesia or fully awake

Question 54

laryngospasm treatment

Answer 54

apply sustained positive pressure with bag-mask ventilation with 100% oxygen, lowdose propofol (0.5-1.0 mg/kg) optional, low-dose succinylcholine (approximately 0.25 mg/kg) and reintubation if hypoxia develops