Inhaled Anesthetics Part 1 (Exam III)

Question 1

What do the pharmacokinetics of inhaled anesthetics describe? (4)

Answer 1

• Uptake from alveoli into pulmonary capillary blood
• Distribution
• Metabolism
• Elimination via lungs

Question 2

What are the influences of old age on inhaled anesthetics? (5)

Answer 2

• ↓ lean body mass
• ↑ fat
• ↑ Vd for drugs (especially for more fat soluble)
• ↓ clearance if pulmonary exchange is impaired
• ↑ time constraints due to lower cardiac output

Question 3

What is Boyle’s Law?
What application of this was mentioned in class?

Answer 3

• Pressure and Volume of gas are inversely proportional
• Bellows contract thus increasing circuit pressure → gasses flow from high pressure (circuit) to low pressure (lungs).
• P ₁ V ₁ =P ₂ V ₂

Question 4

What is Fick’s Diffusion Law (as is pertinent to inhaled anesthetics)?

Answer 4

Once air molecules enter alveoli, they move around randomly and begin to diffuse into the pulmonary capillaries.
- The rate at which a gas moves across a membrane is directly proportional to the concentration gradient (difference in partial pressures) across that membrane.

Question 5

What factors is diffusion dependent on?

Answer 5

• Partial pressure gradient of the gas
• Solubility of the gas
• Thickness of the membrane

Question 6

What is Graham’s Law of Effusion?

Answer 6

Process by which molecules diffuse through pores and channels without colliding.
- The rate at which a gas escapes from a container (effusion) is inversely proportional to the square root of its molecular weight.
- This means a lighter gas will effuse faster than a heavier gas at the same temperature

Question 7

Smaller molecules effuse(escape a container i.e. lungs) faster dependent on ________.

Answer 7

solubility

Question 8

Which diffuses faster CO₂ or O₂ ? Why?
Which would you expect to diffuse faster?

Answer 8

CO₂ is 20x more diffusible due to solubility despite O₂ weighing less.

Question 9

P_A is equal to __ when the inhaled gas concentration equals the exhaled gas concentration and the patient is unconscious.

Answer 9

P_Brain

Question 10

If P_Brain is greater than P_A, what would we expect to be occurring? Why?

Answer 10

The patient should be waking up. This means the exhaled gas is greater than the inhaled gas and the concentration gradient is moving towards the alveoli away from the brain.

Question 11

What does the following equation mean?

P_A ⇌ P_a ⇌ P_Brain

Answer 11

This is comparing the partial pressure of volatile gas in the alveoli to the arterial blood to the brain.

Question 12

Input

What input factors affect the diffusion of volatile gas from the anesthetic machine to the alveoli? (4)

Answer 12

• Inspired partial pressure
• Alveolar ventilation (More ventilation=More drug)
• Anesthetic system re-breathing
• FRC

Question 13

Uptake

Which factors affect the uptake of anesthetic gas from the alveoli to the blood?

Answer 13

• Blood:gas partition coefficient (does your gas favor the blood or does it like to be free?)
• Cardiac output (Speed of bloodflow determines amount of gas exchange)
• A-V pressure difference

Question 14

How would a low cardiac output affect the diffusion of anesthetic gas from the alveoli to the pulmonary capillary blood?

Answer 14

↓CO = more time to diffuse across the alveolus=higher concentrations more quickly

Question 15

What factors affect the uptake of anesthetic gas from the arterial blood to the brain?

Answer 15

• Blood:Brain partition coefficient
• Cerebral blood flow
• A-V partial pressure difference.

Question 16

Gas goes from a ____ gradient to a ____ gradient in order to reach a steady state.

Answer 16

high; low

Question 17

What does P_I mean?

Answer 17

Partial pressure of inspired volatile gas.

Question 18

How can gas be “forced” to the brain quicker?

Answer 18

By increasing P_I. This creates a higher gradient for the gas to flow from P_A → P_a → P_Brain

Question 19

What does F_E/F_I mean?

Answer 19

F_E/F_I is the ratio of expired gas to inspired gas.

Question 20

What concept is this chart conveying?

Answer 20

Concentration Effect: essentially, ↑concentration inspired gas = ↑P_A = increased rate of diffusion
- The higher the concentration of gas (in this case Des) the closer we get to reaching an FE/FI of 1.

Question 21

What is over-pressurization?

Answer 21

• A large increase in P_I so as to force gas from P_A → P_a → P_Brain much faster.
• Example given in class was 1 vital capacity breath of 7% sevo(high-concentration) may be enough for your patient to lose their eyelash reflex.

This is a very temporary “momentatry” dose. Prolonged over-pressurization leads to quicker/worse S/E and potential overdose.

Question 22

What would sustained delivery of over-pressurization result in?

Answer 22

Overdose

Question 23

What gas does the second gas effect always apply to?

Answer 23

N₂O (nitrous oxide)

Question 24

What is the second gas effect as it relates to anesthesia?

Answer 24

• Uptake of N₂O accelerates a concurrently administered volatile gas.

N₂O gets absorbed very quickly. When left with remaining gas, its % is drastically increased, allowing for more uptake across the alveoli.

Question 25

How does N₂O create the second gas effect?

Answer 25

N₂O hyper-concentrates volatiles to create a high concentration gradient after it diffuses across the alveoli.

Question 26

Describe what is being depicted on the graph below.

Answer 26

- This is the concentrating effect of N₂O on halothane. ## Footnote Notice that the % of administered halpothane does not change but its concentration increases as the N₂O amount increases.

Question 27

What cases would nitrous oxide **not** be utilized in? Why?

Answer 27

- Cases with an air-filled cavity - N₂O will diffuse into the cavity and fill it. (extent of damage dependent on the compliance of the cavity).

Question 28

What specific cases are bad for the usage of N₂O?

Answer 28

- Ear (Pain) - Eye (Retinal artery ischemia) - Open belly (Can't put guts back in) - Lung

Question 29

What factors affect the degree of pressure N₂O would exert on a cavity that it filled?

Answer 29

- Partial pressure of N₂O - Blood flow to the cavity - Duration of N₂O administration

Question 30

What would nitrous inhalation in a patient with pneumothorax do?

Answer 30

Expand the pneumothorax ## Footnote Nitrous loves to infiltrate existing air-filled cavities. If the cavity is compliant (lungs) it will increase in volume, thus expanding the existing pneumo.

Question 31

What could N₂O on an intraocular case do?

Answer 31

- Massively increase retinal artery pressure and cause permanent vision loss.

Question 32

Decreased P_aCO₂ from hyperventilation will decrease cerebral blood flow. This will limit __.

Answer 32

induction speed ## Footnote If CBF decreases, there is less gas getting to the brain.

Question 33

Referencing spontaneous vs. mechanical ventilation, how do volatile gases affect the body?

Answer 33

- Volatile gases provide dose dependent depressant effects of alveolar ventilation. In spontaneous ventilation, this creates a negative feedback loop to maintain P_A ⇌ P_a ⇌ P_Brain - Mech. Ventilation removes the above response because the anesthesia provider controls all the variables. This puts the patient at increased risk of overdose. ## Footnote Quoting the Great Corndog, "you gotta be mindful of that."

Question 34

What is the definition of solubility for anesthetic gasses?

Answer 34

**Ratio** of how inhaled gas distribution between two compartments **at equilibrium** (when partial pressures are equal). - Solubility is the relative capacity of each compartment to hold a volatile ## Footnote "Not a volume, not a weight, not a percent...a ratio." -Dr. K This ratio is in parts compared to 1

Question 35

If the temperature of blood increases then solubility ______.

Answer 35

decreases - This means more gas will leave blood and affect brain Don't forget that an increase in temperature also usually means increased metabolism which inevitably means that you must give increased MAC to maintain adequate anestesia (usually)

Question 36

What does a low blood solubility mean for induction?

Answer 36

Less gas has to be dissolved. This means P_A → P_a is rapid = rapid induction.

Question 37

What does a high blood solubility mean for induction?

Answer 37

More gas has to be dissolved so P_A → P_a is slow = slow induction.

Question 38

What is being described in the graph below?

Answer 38

How quickly the inspired concentration of a gas equals the alveolar concentration of said gas.

Question 39

What volatile gasses are intermediately soluble?

Answer 39

- Halothane - Enflurane - Isoflurane

Question 40

What is the blood:gas partition coefficient of halothane?

Answer 40

Halothane = 2.54

Question 41

What is the blood:gas partition coefficient of enflurane?

Answer 41

Enflurane = 1.90

Question 42

What is the blood:gas partition coefficient of Isoflurane?

Answer 42

Isoflurane = 1.46

Question 43

What volatile gasses are poorly soluble?

Answer 43

- N₂O - Desflurane - Sevoflurane

Question 44

What is the blood:gas partition coefficient of N₂O?

Answer 44

Nitrous = 0.46

Question 45

What is the blood:gas partition coefficient of Desflurane?

Answer 45

Desflurane = 0.42

Question 46

What is the blood:gas partition coefficient of Sevoflurane?

Answer 46

Sevoflurane = 0.69

Question 47

What are the blood:gas solubilities of all the gasses we have to know for anesthesia pharm? (Thankfully there are only 6)

Answer 47

Question 48

What occurs (regarding our partial pressure gradients) during emergence from anesthesia?

Answer 48

Concentration gradient reverses. P_A ← P_a ← P_Brain - This washout typically occurs rapidly and depends on the length and type of volatile administration. - Don't need to know numbers, but have to understand that higher Fat:Blood coef. results in longer emergence time (especially if cases is longer)

Question 49

Regarding volatiles, what does it mean when PI is 0?

Answer 49

It means the inhaled agent is turned off silly.

Question 50

What color coding does isoflurane have?

Answer 50

Purple

Question 51

What color coding does sevoflurane have?

Answer 51

Yellow

Question 52

What color coding does desflurane have?

Answer 52

Blue

Question 53

Why would you want to use a volatile anesthetic with a slower emergence time?

Answer 53

You might have to take your patient to an ICU across the hospital and don't want them to wake up in transit. - Be nice to the ICU nurse and give them a sleepy/comfortable patient so they can catch up on their charting. Who knows, maybe they are studing for CRNA school!

Question 54

Which anesthetic would you anticipate as having the quickest recovery? Slowest? Why?

Answer 54

Fastest recovery = desflurane Slowest recovery = halothane Who knows? Maybe because Desflurane has the lowest Fat:Blood Coef and Halothane has the highest. This isn't the end all be all reason though. For example, iso is slower than sevo with a lower Fat:Blood coef but iso does have a much higher blood:gas coef.

Question 55

What helps decrease concentration of volatile anesthetic in P_A and P_Brain on emergence?

Answer 55

Continued uptake by Muscle/Fat if not already at equilibrium.

Question 56

What would ED₅₀ be equivalent to in regards to MAC?

Answer 56

1 MAC

Question 57

What is 1 MAC?

Answer 57

The concentration at 1 atm that prevents skeletal muscle movement in response to supramaximal, **painful** stimulation in 50% of patients ## Footnote At 1 MAC, if the surgeon cuts you with their samurai sword (scalpel), there is a 50/50 chance you wouldn't move.

Question 58

What would ED₉₈ be equivalent to in regards to MAC?

Answer 58

ED₉₈ ≈ 1.3 MAC

Question 59

What is 1.3 MAC?

Answer 59

Concentration at 1atm that prevents skeletal muscle movement in response to surgical stimulation in 98% of patients. ## Footnote At 1.3 MAC, if the surgeon cuts you with their steak knife (scalpel), there is a 98% chance you wouldn’t move.

Question 60

What is MAC_awake?

Answer 60

0.3 - 0.5 MAC: partial awakeness and responsiveness.

Question 61

What is MAC_BAR? Is this MAC safe?

Answer 61

1.7 - 2.0 MAC: Blunts autonomic responses. No SNS response at all, essentially an overdose. No, an overdose isn't ever really "safe"

Question 62

What patient are standardized MAC values based on?

Answer 62

30 - 55 y/o at 37°C at 1atm (760mmHg/torr)

Question 63

What is the MAC of N₂O? What does this mean?

Answer 63

N₂O MAC = 104%. Can't be used as sole anesthetic agent (can't go above 100%).

Question 64

What is the MAC of Halothane?

Answer 64

0.75%

Question 65

What is the MAC of Enflurane?

Answer 65

1.63%

Question 66

What is the MAC of Isoflurane?

Answer 66

1.17%

Question 67

What is the MAC of Desflurane?

Answer 67

6.6

Question 68

What is the MAC of Sevoflurane?

Answer 68

1.8%

Question 69

What are the two biggest factors that affect MAC?

Answer 69

- Body temperature - Age

Question 70

At what age does MAC need peak?

Answer 70

1 y/o

Question 71

How much does MAC need decrease as one gets older?

Answer 71

6% per decade after 55yr

Question 72

What factors will increase MAC requirement? (4)

Answer 72

- Hyperthermia - Excess Pheomelanin (redheads) - Drug-induced ↑ catecholamines (pheochromocytoma) - Hypernatremia (More Na+=More membrane depolarization)

Question 73

What factors will decrease MAC requirement? *Extensive list*

Answer 73

**Essentially anything that slows metabolism** - Hypothermia - Pre-op meds - Intra-op opioids - α-2 agonists (Dex, clonidine) - Acute EtOH - Pregnancy - Early post-partum - Lidocaine - PaO₂ < 38 mmHg - Mean BP < 40mmHg - Cardiac Bypass - Hyponatremia - ↑ Age - Renal Failure - Hypovolemia - Poor Nutrition - History of Stroke

Question 74

What factors have no effect on MAC?

Answer 74

- Chronic alcohol abuse (MEOS Pathway) - Gender - Duration of anesthesia - PaCO2 15-95 mm Hg - PaO2 > 38 mm Hg - Blood pressure > 40 mm Hg - Hyper/hypokalemia (Interesting) - Thyroid gland dysfunction (Average, not thyroid storm. Memaw is probably taking her synthroid)

Question 75

How do volatiles cause immobility (Spinal)? (3)

Answer 75

- Depress excitatory AMPA and NMDA (glutamate receptors) - Enhance inhibitory glycine receptors (Strychnine, glycine antagonist) - Act on sodium channels (Blocks presynaptic release of glutamate)

Question 76

How does loss of consciousness occur with the use of volatile anesthetics?

Answer 76

- Potentiation of GABA_A transmission in the brain and especially in the reticular activating system (RAS) - Potentiation of glycine in the brainstem.

Question 77

Which of these two liquids in enclosed containers has the higher vapor pressure?

Answer 77

Liquid B: more evaporative. *Vapor pressure is the pressure at which vapor and liquid are at equilibirum.*

Question 78

What is Dalton's law?

Answer 78

- The sum of all partial pressures will equal the total pressure. - P_total = P_gas1 + P_gas2...

Question 79

Heat will _____ vapor pressure.

Answer 79

increase

Question 80

Cold temperatures will _____ vapor pressure.

Answer 80

decrease.

Question 81

A lower vapor pressure gas is inherently more volatile. T/F ?

Answer 81

False. ↑vapor pressure = ↑volatility - ↑vapor pressure=↑chance of evaporation when exposed to atmosphere

Question 82

What is the vapor pressure of halothane?

Answer 82

243 torr (mmHg)

Question 83

What is the vapor pressure of Enflurane?

Answer 83

175 torr (mmHg)

Question 84

What is the vapor pressure of Isoflurane?

Answer 84

238 torr (mmHg)

Question 85

What is the vapor pressure of Desflurane?

Answer 85

669 torr (mmHg)

Question 86

What is the vapor pressure of Sevoflurane?

Answer 86

157 torr (mmHg)

Question 87

Partial Pressure/Total Pressure=__

Answer 87

Volumes% - ET and Ins must be equal to have equilibrium of inhaled gas

Question 88

What is the variable bypass on the anesthetic machine?

Answer 88

A way to dilute/concentrate the amount of anesthetic gas reaching the patient.

Question 89

What is the splitting ratio?

Answer 89

How much gas is being sent into the vaporizer

Question 90

What is the purpose of the wicks found in the vaporizing chamber below?

Answer 90

The wicks increase gas-liquid interface (↑surface area) and **improve vaporization**.