Test 3: General Principles of Inhaled Anesthetics (pt 2)

Question 1

What is Stage 1 of Anesthesia?

Answer 1

Analgesia.
-Patient is conscious and rational
-Perception of pain is diminished
-Ex: Monitored anesthesia care (MAC) cases
-Patient may drift off, but should come back easily.

Question 2

What is Stage 2 of Anesthesia?

Answer 2

Delirium/Agitation.
-Patient is unconscious, but body responds reflexively and irrationally to stimuli.
-Usually fast with induction but longer with emergence
-Patients may hold their breath, but airway reflexes are intact, pupils are dilated, eyes are not conjugated.
-Don’t extubate during this

Question 3

What is Stage 3 of Anesthesia?

Answer 3

Surgical Plane of Anesthesia
-Increasing degrees of muscle relaxation
-Loss of pharyngeal reflexes (patient is unable to protect airway)
-HR and RR slow -> Apnea

Question 4

What is Stage 4 of Anesthesia?

Answer 4

Medullary Depression (vasomotor center in the medulla and respiratory center in the brainstem)
-Cardiovascular and Respiratory collapse
-Can lead to death

Question 5

What is the Ventilation Effect?

Answer 5

The faster and more deeply a patient breathes or is ventilated, the faster the patient loses consciousness at the start of anesthesia and emerges at the end.
-INH agents move down a concentration gradient
-Anesthetic uptake slows throughout the procedure as the tissue compartments become saturated (gradient changes)

Question 6

Increasing minute ventilation (RR and Tidal Volume) will do what to the onset/offset of anesthetic effects?

Answer 6

The faster and deeper a patient breathes: (can increase minute ventilation: RR and VT)
-Speeds the onset/offset of anesthetic effects
-Speeds induction
-Speeds emergence

Question 7

How are gases eliminated?

Answer 7

They are ventilated out.

Question 8

How does poor lung function or V/Q mismatch affect INH agents?

Answer 8

-Prolonged onset and emergence.
-Rapid-acting (low blood/gas solubility) agents are affected by these deficits to a greater extent than are slower-acting (high blood/gas solubility) drugs.
-These decreases in speed can be partially compensated for by increasing the concentration of insoluble (fast) agents or increasing ventilation with soluble (slow) drugs.

Question 9

What populations have poor lung function or V/Q mismatch that will prolong onset/emergence?

Answer 9

-COPD, Pulmonary Fibrosis, Kyphosis, Obesity/pregnancy

Question 10

What is the Concentration Effect?

Answer 10

During the first minutes of gas administration, a higher concentration of the drug than necessary for maintenance (above MAC), or a loading dose, is delivered to speed initial uptake. This is commonly referred to as overpressuring or the concentration effect.
-Beware of side effects (hypotension)
-Works better with slower agents and not as good with faster acting agents.

Question 11

How does concentration of an INH agent affect the onset of action?

Answer 11

Higher concentration = faster onset of action.

Question 12

How do you calculate FA (Alveoli Fractional %)?

Answer 12

Ex: 10% agent and 90% O2. 50% of agent flows down conc gradient into the blood. Left with 5% agent and 90% O2. 5/95 = 5.3% in the alveoli. This is how you arrive at FA (Alveoli fractional %). Agent present in the alveoli.

Question 13

What is the Second Gas Effect?

Answer 13

Simultaneous administration of a relatively slow agent such as isoflurane and a faster drug such as nitrous oxide (in high concentrations) can speed the onset of the slower agent. This is known as the second-gas effect.
-Increases uptake on the Alveolar Side. Fills alveoli, pushing the slow agent across.
-N2O acts as a carrier, pulling the slower agent in and moving it faster.
-MOA is unknown
-Works well with a slower agent, but has less of an effect on a faster agent.
-Can be used during emergence also to rapidly eliminate volatile agents by eliminating N2O

Question 14

How does increases in CO affect the onset of action of INH agents?

Answer 14

The higher the CO, the faster the INH agent is carried away from the lungs.
-Slows the rise of the brain and the lung concentration

Katzung:
An increase in pulmonary blood flow (ie, increased cardiac output) will increase the uptake of anesthetic, thereby slowing the rate by which FA/FI rises and decreasing the rate of induction of anesthesia. The increased uptake of anesthetic into the blood caused by increased cardiac output will be distributed to all tissues. Since cerebral blood flow is well regulated and maintained relatively constant at clinical anesthetic concentrations, the increased anesthesia uptake caused by increased cardiac output will predominantly be distributed to tissues that are not involved in the site of action of the anesthetic.

Question 15

The majority of blood/agent leaving the lungs is normally distributed where?

Answer 15

To the Vessel Rich Group (VRG)
-Heart, liver, kidneys, brain
-10% of body weight, but gets 75% of CO.
-Also called the Central Compartment.

The longer the anesthetic is delivered, the greater the perfusion to all body parts

Question 16

Where does Nitrous Oxide diffuse to?

Answer 16

Air containing cavities in the body.
-Normally these cavities are rich in Nitrogen, which is 34 times less soluble than N2O.
-If the space is expandable, it will increase in volume.

Question 17

What are examples of expandable air cavities to avoid N2O with?

Answer 17

-air embolism
-pneumothorax
-acute intestinal obstruction
-intraocular air bubbles produced by sulfur hexafluoride gas injection,
-pneumoperitoneum

Avoid in trauma situations.

Question 18

What equipment is air filled and could expand during N2O anesthesia?

Answer 18

-ETT cuff
-LMA cuff
-Pulmonary Artery Catheter balloon

Question 19

What will occur in rigid air-containing spaces with N2O Diffusion?

Answer 19

Rigid air-containing spaces will undergo an increase in pressure.
-This includes tympanic membrane grafting after tympanomastoid procedures and intracranial air during diagnostic or surgical intracranial procedures.

Question 20

75% Nitrous Oxide will do what with a Pneumothorax?

Answer 20

Double it in 10 min
Triple it in 30 min

Question 21

Rate of induction is faster in adults or children?

Answer 21

Children go to sleep faster than adults
-Uptake is faster (The child’s higher alveolar ventilation specifically related to their increased respiratory rate accounts for this effect.)
-INH agents are less blood soluble in children (they want to go into the tissues)

Question 22

How does MAC Change with Neonates and Infants?

Answer 22

-Neonates: Decreased MAC (first 28 days of life)
-Infants aged 6 months have a MAC 1.5-1.8 times higher than a 40 year old.

Question 23

How does emergence differ in pediatrics?

Answer 23

-Reactions and agitation can occur.
-Robust stage 2 phase that can persist even through stage 1 (delirious/agitated
-Risk factors: preschool age 2-5 years, separation anxiety, and post-op pain.
-Tx with propofol, Fentanyl, Ketamine, or Precedex. Remove stimulating things.

Question 24

How does Obesity affect the uptake of INH agents?

Answer 24

NO Clinical effect on uptake.
-Longer procedures = inc deposition of anesthetics into fat and may prolong recovery.
-Higher fat stores. After >4 hr procedures, gases are really saturating fat compartment. Wakeup/emergence is prolonged. Gases hang on tightly and don’t want to come off (especially Iso)

Question 25

How does Pregnancy affect uptake of INH agents?

Answer 25

-Increased Minute Ventilation = inc uptake
-Increased CO = dec uptake
These two balance each other out, so that the uptake of anesthetics in pregnant women overall is similar to that in a nonpregnant woman.

MAC levels are reduced due to circulating progesterone levels

Question 26

What is the Ventilation Effect (textbook definition)?

Answer 26

The greater the alveolar ventilation, the faster the patient achieves anesthesia.

Question 27

What is the Concentration Effect (textbook definition)?

Answer 27

The higher the concentration of anesthetic delivered, the faster anesthesia is achieved; this is also referred to as overpressuring; as with any drug, the larger the initial dose administered, the faster the onset of action.

Question 28

What is the Blood:Gas Solubility Coefficient (textbook definition)?

Answer 28

The blood/gas solubility coefficient is the indicator of an anesthetic’s speed of onset and emergence: the higher the coefficient, the slower the anesthetic; conversely, the lower the coefficient, the faster the anesthetic.

Question 29

What is the Oil:Gas Solubility Coefficient (textbook definition)?

Answer 29

The oil/gas solubility coefficient is the indicator of an anesthetic’s potency: the higher the coefficient, the more potent the agent.

Question 30

What is the second gas effect (textbook definition)?

Answer 30

The second-gas effect is a phenomenon in which two anesthetics of varying onset speeds are administered together: a high concentration of a fast anesthetic such as nitrous oxide is administered with a slower second anesthetic gas; the slower gas achieves anesthetic levels more quickly than if it had been given alone.

Question 31

What is Diffusion Hypoxia (textbook definition)?

Answer 31

Diffusion hypoxia occurs when high concentrations of nitrous oxide are administered; at the end of the procedure, when nitrous oxide is discontinued, it leaves the body very rapidly, causing a transient dilution of the oxygen and carbon dioxide in the lungs; hypocarbia and hypoxia may occur; administration of 100% oxygen for approximately 3–5 min when nitrous oxide is discontinued alleviates this problem.

Question 32

How does CO effect uptake of anesthetics (textbook definition)?

Answer 32

Increases in cardiac output decrease the speed of onset of all anesthetics; the more soluble anesthetics are affected to a much greater extent than the insoluble anesthetics.

Question 33

How do Ventilation-Perfusion Abnormalities affect anesthetics (textbook definition)?

Answer 33

Ventilation-perfusion abnormalities reduce the speed of onset of all anesthetics and affect the insoluble agents to a much greater degree than the soluble agents.

Question 34

How do pediatric patients differ from adults with anesthetics? (Textbook definition)

Answer 34

Children achieve anesthesia more rapidly than adults because of a higher ventilatory rate and vessel-rich group blood flow; this occurs despite the fact that the required dose and cardiac output are higher in children.

Question 35

How does obesity affect anesthetics (textbook definition)?

Answer 35

Obesity has minimal clinical effects on anesthetic induction; however, emergence may be slower because of deposition of anesthetics in fat.

Question 36

How does pregnancy affect anesthetics (textbook definition)?

Answer 36

The kinetics of the inhalation anesthetics are similar in pregnant women and nonpregnant women; placental transfer is time dependent as expected.

Question 37

What is the purpose of the CO2 Absorber?

Answer 37

-Allows for rebreathing
-Conserves agent, O2, N2O, and humidity without rebreathing CO2.
-Dec FGF = inc Absorption
-Prevents Respiratory Acidosis. Everything goes through the absorber, CO2 is scrubbed out, and gases are recycled.

Question 38

What can happen to the CO2 Absorbent with too much FGF?

Answer 38

-Can cause it to dry out (Dessication)
-Produces CO and heat
-CO poisoning is difficult to detect
-CO production especially occurs with dry sodalime.

Question 39

How do you know if your sodalime is dry?

Answer 39

-Sodalime needs water to produce the reaction. Approx. 10-20% of its weight is water.
-Sodalime will dry out at high FGF and if O2 is left on overnight.
-Ethel Violet color change = exhaustion of sodalime
-Color can revert during a rest period back to white.

If it’s exhausted during the case, you can increase FGF to help blow off the CO2.

Question 40

Which agents produce the most CO?

Answer 40

Desflurane > Isoflurane
Halothane & Sevo produce very little.

Question 41

What does Sevoflurane degrade to?

Answer 41

Compound A
-Nephrotoxic
-Lethal in rates
-Increased production occurs due to low flow or closed circuit systems, or due to warm/very dry CO2 absorbent (drying occurs due to exothermic rxn)
-Do not administer at <2L/min FGF for more than 2 MAC Hours

Question 42

What is a MAC Hour?

Answer 42

If you’re using 1 MAC of gas, that’s 2 MAC hours
-Theoretical

Question 43

What is Halogenation?

Answer 43

The addition of Fluorine, Chlorine, Bromine, or Iodine to a hydrocarbon or ether.
-Changes its potency, arrhythmogenic properties, flammability, and chemical stability (oxidation during storage and rxns with bases)
-Reduced flammability compared to Ether

Question 44

Which agents contain “Ether Bridges” in their chemical structure?

Answer 44

Iso, Des, and Sevo

Question 45

What is the chemical structure of Halothane?

Answer 45

-Halogenated Hydrocarbon.
-Has Bromine (alkane)
-Inc risk of arrhythmias (avoid in HB patients)

Question 46

Anesthetic effect is lost if the carbon atom length exceeds how many atoms?

Answer 46

4 or 5 atoms.

Question 47

How many flourines are seen with Iso?

Answer 47

5
-Example of a trifluorocarbon (adds stability)

Question 48

How many flourines are seen with Des?

Answer 48

6

Question 49

How many flourines are seen with Sevo?

Answer 49

7

Question 50

How does Fluorination affect the chemical structure of the agent?

Answer 50

Reduces solubility in both blood & fat

Question 51

Rank the agents in order of Most to Least metabolized.

Answer 51

SEVO > ISO > DES > N2O
-Desflurane resists biodegradation even after 7.35 MAC hours (it contains fluorine as its only halogen - makes it less soluble)
-N2O Is not metabolized by human tissues.

Question 52

What is the MOA of INH agents?

Answer 52

-Result of multiple mechanisms – no one really knows for sure
-Probably due to multiple interactions with diverse ion channels in the brain. No single receptor explains the actions of INH agents.
-Effects of the anesthetic state (amnesia, sedation/unconsciousness, analgesia, and immobility) are due to separate effects on different receptors and neuronal pathways.

Question 53

What are the effects of INH agents on the spinal cord?

Answer 53

-Prevention of skeletal muscle movement (Immobility) at increasing doses.
-Potentiation of glycine receptors in the spine.
-Acts on spinal cord central pattern generators
-Probably due to effects on glycine, sodium, NMDA receptors

PPT says it doesn’t involve GABA, but Nagelhout says:
“The spinal cord is known to mediate immobility to a painful stimulus via several mechanisms, including reducing spontaneous action potential firing of spinal neurons via glycine receptors and γ-aminobutyric acid type A (GABA A ) receptors”

Question 54

How do INH agents produce amnesia?

Answer 54

-Effects on the hippocampus, amygdala, other cortical structures (Neocortex)
-Potentiation of GABA A5 subunit increases Chloride conductance
-Regulates hippocampus and short term memory

Question 55

How do INH agents produce unconsciousness?

Answer 55

Via effects on the cerebral cortex, thalamus, and brainstem reticular formation

Question 56

What is the Unitary Hypothesis?

Answer 56

The theory that all agents work via a similar, although undefined, MOA, but not necessarily at the same site of action.
-Supported by the Meyer-Overton theory
-Older theory

Question 57

What is the Meyer-Overton Theory?

Answer 57

Theory that correlates lipid solubility and potency.
-Lipid solubility is directly proportional to potency.
-More or less debunked (not supported by research)

Question 58

Do neuronal nAchR affect immobility?

Answer 58

Does not contribute to the immobility of INH agents

Question 59

What is the effect of Volatile Agents on Neuronal Na Channels?

Answer 59

Blockade

Question 60

What is the effect of Volatile Agents on NMDA-like receptors & Glutamate receptors?

Answer 60

-Inhibits glutamate release
-CNS Depression

“Inhaled anesthetics suppress excitatory synaptic transmission presynaptically by reducing glutamate release (inhalation anesthetics) and postsynaptically by inhibiting excitatory ionotropic receptors activated by glutamate (gaseous and to some extent inhalation anesthetics).”

Question 61

What are the general principles of an Ideal INH Agent?

Answer 61

-Able to produce unconsciousness, analgesia, and immobility
-Pleasant smell (non irritating, pleasant induction)
-Low B:G solubility (rapid induction/recovery)
-Stable in storage
-Non-flammable/non-explosive
-Non-toxic/non-allergenic (not metabolized by body)
-Readily reversible CNS effects (No CNS Stimulant activity)
-Sufficient potency (allows use of high FiO2)
-Minimal CV and Resp depression
-No interactions with other drugs (espec anesthesia related drugs)
-Eliminated completely (rapidly, and unchanged via the lungs)