SS25 3-10 Inhaled Anesthetics Part 2 (Exam 3)

Question 1

What are the purposes of the anesthesia circuit?

Answer 1

• Delivers O₂ and inhaled anesthetics
• Maintenance of temperature & humidity
• Removal of CO₂ and exhaled drugs

Question 2

Explain how the anesthesia circuit maintains temperature/ humidity.

Answer 2

Utilizes the nose/pharnyx to maintain natural moisture and warmth

Question 3

What types of gas delivery systems are there?

Answer 3

• Rebreathing (Bain system)
• Non-rebreathing (self-inflating BVM system)
• Circle systems (Anesthesia machine)

Question 4

• Why is the BVM system a great way to give volatile anesthetics?
• What is the key difference with the BVM reservoir bag?
• What can you add to BVM system?

Answer 4

**- Trick question! ** Non-rebreathing BVM system is not a good way for inhaled drugs. It’s very effective for O2 and air delivery.
- Must self-inflate
- Able to build on it: add peep; add another bag; add O2

Side note:The way the BVM is set up can control how much re-breathing we have

Question 5

What type of system is depicted below?
Where is the aPL valve located on this system?

Answer 5

• Bain Circuit = Rebreathing
• Blue circle depicts aPL below.

Question 6

List key characterictics of Bain circuit based on labeled points

Answer 6

• A: Patient end that connects to ETT
• B: Able to connect to supplemental O2 via side port
• C: Another O2 connector option
• D: Acts as typical reservior bag
• E: APL valve open/ shut to make bag inflate more or less (control positive pressure)

Question 7

In the figure below, what portion of the anesthesia circle system is indicated by 1?

Answer 7

Inspiratory Unidirectional Valve

Question 8

In the figure below, what portion of the anesthesia circle system is indicated by pink arrow?

Answer 8

Fresh Gas Inlet (O₂ & medical air)

Question 9

In the figure below, what portion of the anesthesia circle system is indicated by 2?

Answer 9

CO₂ Absorber

Question 10

In the figure below, what portion of the anesthesia circle system is indicated by 3?

Answer 10

Bag/Ventilator Selector Switch

Bag inspiratory drive v. vent inspiratory drive

Question 11

In the figure below, what portion of the anesthesia circle system is indicated by 4?

Answer 11

APL Valve

Question 12

In the figure below, what portion of the anesthesia circle system is indicated by 5?

Answer 12

Expiratory Unidirectional Valve

Question 13

In the figure below, what portion of the anesthesia circle system is indicated by 6?

Answer 13

Expiratory Limb

Question 14

In the figure below, what portion of the anesthesia circle system is indicated by 7?

Answer 14

Y-Piece
- ETT connection

Question 15

What is a drawback of the circle gas delivery system?

Answer 15

It is stationary, not portable

Question 16

This is the only gas delivery system with a CO₂ absorber and always has a reservoir bag. Where as the other gas delivery systems may or may not have a reservoir bag

Answer 16

Circle System

Question 17

When fresh gas flow (FGF) exceeds V̇_m then you have _________________.

Answer 17

High Flow Anesthesia

Question 18

When V̇_m exceeds fresh gas flow (FGF) then you have _________________.

Answer 18

Low Flow Anesthesia

Question 19

When would one see rapid changes in anesthetic, lack of rebreathing, wasteful volatile use, and cool dried air?

Answer 19

High Flow anesthesia

Question 20

What are common indications for high flow delivery?

Answer 20

• Build up O2 reserve (Pre-oxygenate)
• Rid N2 (Denitrogenate)
• Esp. in elderly and comorbid populations

Question 21

For high flow anesthesia, you want to ____ (increase/decrease) gas concentration and ____ (increase/decrease) flow rate.

Answer 21

• increase; increase

Question 22

When would one see lower cost d/t less volatile use, less cooling/drying of air, and slow changes in anesthetic?

Answer 22

Low Flow anesthesia

Question 23

What is Compound A?

Answer 23

• Metabolite produced during Low Flow Sevo anesthesia and CO2 absorbent
• Low flow anesthesia (LFA) is 2 L/min (lower than normal Vm)
• Nephrotoxin
• No longer a concern but was prevalent for decades so will still be in literature/ discussed

Question 24

What is the CO2 absorbent made of?
- How is this rlt Compound A?
- What was the rat discovery?

Answer 24

• CO₂ absorbent used to be made of Potassium (K+) and Sodium Hydroxide (NaOH)
• Increase CO₂ absorbant with Low Flow Sevo created Compound A (nephrotoxin)
• Today CO₂ absorbant is made out of calcium hydroxide (>75%)
• Discovered it takes about 100 parts per million (ppm) to cause Acute tubular necrosis (ATN) in rats and 400 ppm to kill them

Question 25

Scientific word for Compound A:

Answer 25

- **Fluoromethyl-2,2-difluro-1-vinyl ether**

Question 26

What do we know about Compound A now in modern day?

Answer 26

- No clinical date to support Compound A is a risk at LFA - Breathing circuit trial: @ flows of 1, 3 , 6 L/min we had 19.7, 8.1, 2.1 ppm - Showed no change in BUN/ creat, no proteinuria & no glucosuria - D/t low ppm not clincally significant - Low Flow anesthesia with the new formula for CO₂ absorbers doesn’t cause enough Compound A formation in adults to be anywhere close to clinically significant

Question 27

What is the quickest way to get a patient to stop responding to surgical stimuli?

Answer 27

- Turn up gas concentration and flow rate

Question 28

Do volatiles cause broncho-constriction or broncho-dilation?

Answer 28

Bronchodilaton

Question 29

How do volatiles cause bronchodilation?

Answer 29

- Blockage of VG Ca⁺⁺ channels - Depletion of SR Ca⁺⁺ - This requires intact epithelium!

Question 30

Is the bronchodilatory effect of volatiles still present in someone with reactive airway disease?

Answer 30

- No (or very little effect). Bronchodilatory effects of volatiles **require an intact epithelium** - inflammatory processes & epithelialdamage alters effectiveness

Question 31

Will volatiles cause bronchospasm on their own (in a patient with no history of bronchospasm)?

Answer 31

No *Histamine release or vagal afferent stimulation needed to cause spasm.*

Question 32

In a patient without history of bronchospasm, how much would you anticipate PVR to change with 1-2 MAC?

Answer 32

PVR would be **unchanged** in patient with no history of bronchospasm.

Question 33

What risk factors increase risk of bronchospasm?

Answer 33

- Coughing w/ ETT in place - <10 years old - URI

Question 34

What anesthetic is generally the best at bronchodilating?

Answer 34

- Sevoflurane (1st) - Isoflurane (2nd)

Question 35

Inhaled anesthetic of choice for pediatric patients:

Answer 35

- Sevoflurane ## Footnote Sevo! Sevo! Sevo!

Question 36

Which anesthetic can function as a pulmonary irritant? - This leads to? - Which population is at an increased risk?

Answer 36

- Desflurane - Worsening bronchospam - Smokers

Question 37

Which volatile anesthetic in the graph below caused the greatest increase in airway resistance? Lowest?

Answer 37

- Desflurane = ↑ airway resistance - Sevoflurane = ↓ airway resistance

Question 38

T/F: Inhaled anesthetics have dose-dependent skeletal muscle contraction mediated via spinal cord.

Answer 38

- False - dose dependent skeletal muscle **Relaxation**

Question 39

Which volatile gas has **no effect** on the relaxation of skeletal muscles?

Answer 39

- N₂O (Nitrous Oxide)

Question 40

Will volatiles potentiate or inhibit depolarizind and non-depolarizing NMBD's? - If so, how?

Answer 40

- **Potentiates ** - via **sensitization of nACh receptors at NMJ** - via **enhancement of glycine at the spinal cord** ## Footnote Side note: Volatile anesthetics cause enhancement of glycine leading to skeletal muscle relaxation as a **solo agent**

Question 41

What is ischemic preconditioning?

Answer 41

Brief periods of ischemia preparing the heart for longer periods of ischemia.

Question 42

Ischemic preconditioning with volatile anesthetics can occur as low as what MAC level?

Answer 42

0.25

Question 43

What molecule mediates ischemic preconditioning?

Answer 43

Adenosine

Question 44

Why does ischemic preconditioning happen? (**IPRV**)

Answer 44

- **Increases PKC** activity - **Phosphorylation of ATP sensitive K⁺ channels** - Production of **ROS** - Better **vascular tone regulation** ## Footnote PKC = Protein Kinase C ROS = Reactive Oxygen Species

Question 45

What does ischemic preconditioning prevent?

Answer 45

- **Reperfusion injuries** - Cardiac dysrhythmias - Contractile dysfunction - Delays MIs for PTCA and CABG

Question 46

At what dose does volatile depression of CMRO₂ and cerebral activity begin?

Answer 46

- 0.4 MAC as wakefulness changes to unconsciosness

Question 47

At what MAC would we see EEG burst suppression? What about total electrical silence?

Answer 47

- 1.5 MAC = burst suppression - 2 MAC = EEG electrical silence

Question 48

At what MAC does 50% of patients not move to supermaximal stimuli (ie: surgical cut)?

Answer 48

- 1.0 MAC

Question 49

Which volatile causes the most EEG suppression?

Answer 49

- Trick question. They all affect EEG's the same. - ''**SID**'' ## Footnote Isoflurane = sevoflurane = desflurane

Question 50

Which volatiles have anticonvulsant activity? - At high or low concetrations? - With hypercarbia or hypocarbia?

Answer 50

- **DIS**: Des, Iso, &Sevo - At **high concentrations** & with **hypocarbia**

Question 51

Which volatile is a proconvulsant? - Risk factors?

Answer 51

- Enflurane - Especially above 2.0 MAC or PaCO2 < 30 mmHg

Question 52

Give an example of a somato-sensory evoked potential (SSEP).

Answer 52

Stimulation of the foot evoking an electrical response in the CNS.

Question 53

Give an example of a motor-evoke potential (MEP).

Answer 53

Direct stimulation of the brain eliciting a twitch response in the hand.

Question 54

You have a case where SSEPs and MEPs need to be monitored, what general anesthetics options do you have?

Answer 54

- TIVA - N₂O 60% and 0.5 MAC volatile

Question 55

What specific effects will volatile agents have on SSEPs and MEPs?

Answer 55

Dose-dependent (0.5 - 1.5 MAC): - ↓ amplitude - ↑ latency (delayed frequency)

Question 56

What effects does volatiles have on cerebral blood flow (CBF)?

Answer 56

- Dose-dependent effects - **↑ volatile adminstration = ↑ vasodilation = ↑ CBF** - Can lead to **↑ ICP**

Question 57

At what MAC onset do you start to see an ↑CBF due to volatile administration?

Answer 57

- Onset > 0.6 MAC ## Footnote Occurs within minutes despite lack of BP change

Question 58

Which volatile has less vasodilatory effects?

Answer 58

Sevoflurane

Question 59

Which volatile has the greatest effect on increasing CBF/ICP?

Answer 59

Halothane

Question 60

Which volatile is the best for neuro cases? Why?

Answer 60

- Sevoflurane - Preserves autoregulation mechanism up to 1 MAC ## Footnote Hesd injuries

Question 61

Is Sevo isn't available what is the next option for volatile use with CBF management?

Answer 61

- Iso and Des pretty much equal effects per Dr. Kane

Question 62

What patient population is most at risk due to the ICP increasing effects of volatile agents?

Answer 62

Patients with space-occupying lesions

Question 63

At what volatile dosage does ICP increase? - How much of an increase do we typically see?

Answer 63

- Onset **> 0.8 MAC** - Increase in ICP by **7 mmHg**

Question 64

What opposes increased ICP?

Answer 64

- Hyperventilation

Question 65

**T/F:** Nitrous is a potent vasodilator

Answer 65

- True - Avoid diffusion into airspaces (ie: pneumocephalus)

Question 66

Explain autoregulation differences between Halo, Sevo, Iso, & Des.

Answer 66

- Sevo preserves to 1 MAC - Halo lost by 0.5 MAC - Iso & Des lost by 0.5 - 1.5 MAC ## Footnote Autoregulation varies patient to patient

Question 67

Based off image, explain autoregulation.

Answer 67

- ICP, MAP, PaCO2, & PaO2 autoregulated between 50 - 150 mmHg - Our goal is tomaintain within autoregulation (MAP > 60 mmHg / within 20% of baseline) - Volatiles can cause **expected** shifts outside of autoregulation; must be prepared to treat those

Question 68

What do volatiles do to the respiratory system?

Answer 68

Dose-dependent: - **Respiratory depression** - ↑ rate (Tachypnea) - ↓ V_T - **The more volatile used, the faster & shallower the patient will breath** ## Footnote The more volatile used, the faster&shallower thr patient will breath

Question 69

How do volatiles cause their respiratory depression?

Answer 69

- Direct depression of medullary ventilatory center - Interference with intercostal muscles - Rate change insufficent to miantin Vm or PaCO2

Question 70

Describe physical change in breathing muscles during respirstory depression.

Answer 70

- Diaphragm descends and chest wall collapses inward

Question 71

At what volatile dosage would **apnea** be seen?

Answer 71

1.5 - 2.0 MAC

Question 72

**T/F:** All volatiles will blunt both the hypoxic and hypercarbic response

Answer 72

- False. **N₂O** does **not** blunt the **hypercarbic response** - N₂O does **not** increase PaCO2 ## Footnote **All volatiles blunt hypoxic response (including N2O)**

Question 73

How can the hypercarbic response be preserved while using volatile anesthetic gasses?

Answer 73

- Use N₂O and volatile together (less depression)

Question 74

What usually mediates blunting of hypoxic response with volatile administration? - At what MAC(s)?

Answer 74

- Mediated by Carotid bodies **- 0.1 MAC= 50 - 70% depression** - **1.1 MAC = 100%** depression

Question 75

Based on image, explain CO2 response to volatile use.

Answer 75

- All volatiles have a significant increase in PaCO2 (except N2O) - Use of N₂O-desflurane decreases CO2-induced hypercarbia compared to desflurane alone.

Question 76

What is hypoxic pulmonary vasoconstriction (HPV)?

Answer 76

- Compesatory contraction of pulmonary artery smooth muscle to shunt blood away from poorly ventilated portions of the lung. - Optimizes VQ

Question 77

When is HPV most concerning?

Answer 77

- In **One-lung ventilation**

Question 78

How fast is the HPV response?

Answer 78

- Fast: **within 5 minutes regional blood flow is ½ of normal** - Max response lasts up to 2 - 4 hours

Question 79

50% depression of HPV occurs at ___ MAC.

Answer 79

- 2 MAC - Volatiles cause a dose-dependent decrease HPV response **but we never give 2 MAC for an entire case so we shouldn't see this ever**

Question 80

Which volatile(s) **does not** cause cardiac depression?

Answer 80

- N₂O (Nitrous)

Question 81

How do volatiles effect MAP? - What dose-dependent changes occur?

Answer 81

- Direct myocardial depression by altering Ca⁺⁺ entry and SR function - **Dose-dependent ↓** in contractility, SVR, CO, & MAP ## Footnote Most decrease seen with Halothane use " H for heart probs"

Question 82

When is volatile depression of cardiac function most concerning?

Answer 82

- In diseased hearts with altered contractility

Question 83

What effect does volatiles have on heart rate?

Answer 83

- Dose-dependent **increases** in HR

Question 84

What volatile can cause significant tachycardia with overpressurization?

Answer 84

- **Desflurane** - Iso and Des can cause increased tachycardia at lower MAC concentrations than Sevo

Question 85

When will sevoflurane begin to cause increases in heart rate?

Answer 85

- Only when > 1.5 MAC

Question 86

What variables cofound/ obscure the tachycardic effect of volatiles?

Answer 86

- Anxiety - Concurrent opioids - β blockade - Vagolytics

Question 87

Compare CI/CO effects of volatile usage.

Answer 87

- Dose- dependent **decrease** in CI/CO - Halothane has most decrease in CO - Isoflurane seems to maintain CO up to about 1 MAC

Question 88

What volatile is sympathomimetic, causing a slight increase in CO?

Answer 88

N₂O

Question 89

What's coronary steal syndrome? - Is it clinically significant?

Answer 89

- Volatiles induce coronary vasodilation on 20-50 mm vessels preferentially - Redistribution of blood from ischemic to non-ischemic regions - Not significant

Question 90

What electrocardiac effect do volatiles have? - This causes an increase risk of what arrythmia?

Answer 90

- QT prolongation via inhibition of K⁺ currents in healthy patients - Torsades ## Footnote Be aware of other meds being used that proolong QT as well (ie: Zofran)

Question 91

Which volatile has minimal pro-arrhythmic activity?

Answer 91

N₂O

Question 92

Which volatile is the choice for EP ablations and why? - Which volatile is poor choice for EP studies and why?

Answer 92

- Sevoflurane; no negative effects with ablations - Isoflurane **increases refractoriness** of accessory pathways making identification of arryhthmia location difficult.

Question 93

Volatile neuroendocrine stress response: will cause a perioperative surge in

Answer 93

- ANS and HPA (**Hypothalamus Pituitary Axis**) activated - Perioperative surge in catecholamines, ACTH, & cortisol ## Footnote "We know a lot about volatiles thanks to **Edmond Eger**" - Dr. Kane

Question 94

Volatiles suppress what important immune system components?

Answer 94

- Volatiles suppress **Monocytes, Macrophages, and T-cells** (MMT)

Question 95

What does the total neuroendocrine profile of volatile anesthetics suggest for cancer patients undergoing surgery?

Answer 95

- Neuraxial anesthesia is likely better than GA for cancer patients - Evidence shows GA increases metastasis and mortality - TIVA may be better choice for Ca patients

Question 96

What hepatic blood flow changes are seen with volatile administration?

Answer 96

- Total hepatic BF maintained - Hepatic artery flow maintained - Portal vein flow **increased** d/t vasodilation

Question 97

What MAC dose does portal vein flow increase?

Answer 97

- 1 - 1.5 MAC

Question 98

Which volatile(s) decrease portal vein flow?

Answer 98

- **Halothane** - Halothane Hepatitis common - Decreases O2 delivery

Question 99

What is volatile hepatotoxicity? -When is it a concern?

Answer 99

- Inadequate oxygenation of hepatocytes via ↓ blood flow, enzyme induction and ↑ O₂ demand - Concern for patients with preexisting liver disease

Question 100

What is Type 1 Volatile hepatotoxicity?

Answer 100

- **Direct toxic or free radical effect 1-2 weeks** post surgically - Flu-like symptoms (N/V, lethargy, & fever) -20% of patients; more common than Type 2

Question 101

What is Type 2 Volatile Toxicity?

Answer 101

- Immune-mediated (IgA) response against hepatocytes caused by **previous exposure to volatile** - Charecterized by eosinophilia & fever - **Occurs 1 month after exposure** - Higher mortality with Acute hepatitis and necrosis ## Footnote Why we don't use Halothane in US

Question 102

Volatile of choice for severe liver disease? - Why?

Answer 102

-**Sevoflurane**: Metabolized to **vinyl halide** - Unable to stimulate antibody production causing a Type II reaction

Question 103

What volatiles are metabolized into **acetyl halides**? - What is the significance of this?

Answer 103

- Enflurane > Iso > Des - Oxidixed by P450 to acetyl halides - **Acetyl halides can cause antibody reactions** especially with previous exposure to Halothane or Enflurane

Question 104

What are the renal effects of volatile anesthetics?

Answer 104

- Dose dependent **decrease** in RBF, GFR, and UO from CO depression - Foleys for surgeries > 2 hrs - **Expect lower UOP d/t volatiles and may be positioning (gravity)** (not rlt to Vasopressin release)

Question 105

How can the renal effects of volatile anesthetics be counteracted?

Answer 105

- Pre-Op Hydration

Question 106

What other organ (besides the heart) undergoes protective ischemic preconditioning from volatile anesthetics?

Answer 106

- Kidneys

Question 107

What toxic metabolites of volatiles can cause nephrotoxicity? - Nephrotoxic presentation? - Why is this not an issue typically?

Answer 107

- Fluoride metabolites - **Hyper**osmolarity, **Hyper**Na, **Increased** creatinine (**HIH**) - Newer volatiles have **lower solubility** so they're **exhaled prior to being metabolized **

Question 108

What volatile is 70% metabolized and can cause fluoride metabolite nephrotoxicity more than any of the other volatiles?

Answer 108

Methoxyflurane ## Footnote Removed from market

Question 109

What measure is utilized in CO₂ absorbents today to help prevent the formation of compound A?

Answer 109

- 75% or greater concentrations of calcium hydroxide [Ca(OH)₂]

Question 110

What volatile is predisposed to starting fires? Why?

Answer 110

- Sevoflurane - Sevo + desiccated absorbent produces **methanol and formaldehyde** causing a heat and speeding up reactiom which can lead to spontaneous combustion

Question 111

How is sevoflurane fire avoided?

Answer 111

- **Add water to Sevo** - **Check temp of absorbent cannister** (should feel like room temp; shouldn't be hot)

Question 112

Malignant Hyperthermia: - Causes - MOA - S&S - Diagnostic test - Treatment

Answer 112

- Caused by all inhaled Volatiles and Succs - MOA: Hypermetabolic state of skeletal muscle: **Excessive Ca release; muscle rigidity; Rhabdo** - S&S: Fever, hypercarbia, hypoxia - Test: Caffeine contracture test - Tx: Dantrolene ## Footnote 80% mortality (high)

Question 113

MOA of Dantrolene:

Answer 113

- Ca-channel blocker - Blocks intracellular Ca release - Supportive care for Rhabdo

Question 114

Which volatile anesthetics are emetogenic?

Answer 114

- **All** ## Footnote Maybe just TIVA; no volatiles

Question 115

What rate of PONV is seen with two triggering agents? - Example of triggering agents?

Answer 115

- 25 - 30% PONV - Volatile + Opioid - Other risk factors: - **Females, abd sx, pregos, red heads** ## Footnote **Pre-op combo drugs**

Question 116

When is N₂O pro-emetic?

Answer 116

- Greater than 0.5 MAC - Just don't give it

Question 117

Metabolic effects of volatiles: (**BMH**)

Answer 117

- B12 deficiency - Megaloblastic BM supression - High plasma homocysteine levels

Question 118

Why is N₂O administration in a pregnant patient with B₁₂ deficiency dangerous?

Answer 118

- N₂O will **oxidize the cobalt ion in B₁₂** thus inhibiting methionine synthase = **inhibition of DNA synthesis in fetus** - High risk: 1st tri pregos

Question 119

Which volatile anesthetic can cause megaloblastic bone marrow suppression?

Answer 119

- N₂O - After 24 hrs after exposure; repeated exposured < 3 days cumulative intervals - high risk: Immunocompromised patients

Question 120

What is the result from increases in plasma homocysteine levels from N₂O administration?

Answer 120

- If the patient also has **low B vitamins** and **atherosclerosis**, then N₂O **increases risk of myocardial events**

Question 121

What are the OB effects of volatile use? At what MAC?

Answer 121

- Dose-dependent **(0.5 - 1.0 MAC)** **decrease** in uterine smooth muscle contractility

Question 122

When would a decrease in uterine muscle tone be useful?

Answer 122

- With retained placenta - Increase volatile to dilate

Question 123

When would an increase in uterine muscle tone be useful?

Answer 123

- Uterine atony (↑ blood loss) - Decrease volatile

Question 124

Why is N₂O useful in mom's post delivery?

Answer 124

- Swiftly increases analgesia without opioid/benzos (use as the spinal starts to wear off) - No effect on contractility

Question 125

Which volatiles have a sweeter smell (non-pungent)?

Answer 125

- Halothane - Sevoflurane

Question 126

Halothane profile: - molecular makeup? - sweet or smelly odor? - high, intermediate, or low solubility?

Answer 126

- Halogenated alkane - Compatible with inhalation induction: high potency; sweet/ non-pungent odor - **Intermediate solubilty** = wants to stay in blood **(so slower induction and a slower wake up)**

Question 127

Benefit(s) of Halothane:

Answer 127

- Lower risk of N/V - Non-flammable

Question 128

What are the four major concerns of Halothane? (**CHPD**)

Answer 128

- Catecholamine-induced arrhythmias - Hepatic necrosis - Pediatric brady-arrhythmias - Decomposing into HCL acid (Thymol preservative added)

Question 129

Which two volatiles can't be used for induction due to their awful smell/pungent?

Answer 129

- Isoflurane - Desflurane

Question 130

Which volatile does not degrade, even after 5 years of storage?

Answer 130

Isoflurane

Question 131

Isomer of Enflurane:

Answer 131

- Isoflurane (Forane) ## Footnote Creation order: Halothane → Enflurane → Isoflurane

Question 132

Which volatile is considered most famous/popular per lecture?

Answer 132

- Desflurane (Suprane) ## Footnote Sevo also very popular

Question 133

Isoflurane profile: - high or low potency? - sweet or smelly odor? - high, intermediate, or low solubility? - name of purification process? - Is it nephro/hepatotoxic? - Shelf life?

Answer 133

- Highly potent - Highly pungent - Intermediate solubiity - $$$ to purify (Distillation) - No, Resistant to metabolism (avoids toxicity) - Stable; no deterioration after 5 years

Question 134

Which inhaled volatile requires a vaporizer with a heating element?

Answer 134

- Desflurane - Requires special vaporizer

Question 135

Desflurane profile: - molecular make up? - what volatile is it very similar to? - what is the difference b/w them?

Answer 135

- Fluorinated methyl **ethyl** ether - Identical to Isoflurane except Fluoride substituted for Chloride

Question 136

Desflurane profile: - high, intermediate, or low potency? - high or low solubility? - sweet or smelly odor? - high or low vapor pressure?

Answer 136

- low potency - low solubility (wants to leave blood and go to receptors) - Most pungent (**coughing, salivation, breath holding, laryngospasm occurs in greater than 6%**) - High vapor pressure 669 mmHg

Question 137

What happens if you over-pressurize Desflurane? - Mediated by what?

Answer 137

- Tachycardia d/t SNS stimulation

Question 138

What does Des degrade into? - Cause? - How could this happen?

Answer 138

- Will degrade into Carbon monoxide (CO) if absorbent dehydrates - Could happen **if you forget to turn O2 flow meter off**

Question 139

List the order in which volatiles will degrade into carbon monoxide if the absorbent becomes exhausted.

Answer 139

- **Desflurane** (worst) > Enflurane > Isoflurane > Sevoflurane (trivial) ## Footnote **DEIS**

Question 140

Which volatile anesthetic would be the choice for inhalation induction? Why?

Answer 140

- Sevoflurane - Smells sweet = **Least airway irritation of modern volatiles**

Question 141

Sevo profile: - molecular make up? - High or low solubility?

Answer 141

- Fluorinated methyl **isopropyl** ether - low solubility

Question 142

Neuro effects of Sevo: - How does it effect ICP? - How does it effect lidocaine-induced seizures?

Answer 142

- Least cerebral vasodilation - **Drug of choice (DOC) for increased ICP** - **Supresses** lidocaine-induced sz activity

Question 143

Pop Quiz: What's the blood:gas coefficient for Sevo and Des? - Which one has the lower/poorer solubility? Clinical significance?

Answer 143

- Sevo = 0.69 - Des = 0.42 (lower solubility) - **The lower the solubilty the more it wants to leave blood and go to receptors in brain (VRG), fat, etc.**

Question 144

Sevo metabolism: - Metabolite? - Does is for CO and Compound A?

Answer 144

- Inorganic Fluoride - All volatiles can form CO but Sevo is **least likely** - We now know it won't form toxic levels of Compound A from Low Flow ## Footnote Sevo = super safe and predominant volatile

Question 145

Nitrous Oxide (N₂O) profile: - high or low potency? - sweet or smelly odor? - high, intermediate, or low solubility?

Answer 145

- Low potency - Sweet/odorless - Lowest solubility

Question 146

How does N₂O produce skeletal muscle relaxation?

Answer 146

- Trick question! **It does not**. - **Unable to be sole anesthetic b/c can't deliver1 MAC**

Question 147

What are the benefits of N₂O ?

Answer 147

- Good analgesic properties (ie: spinal wearing off, dentist fillings) - 2nd gas effect

Question 148

What's 2nd gas effect?

Answer 148

- Quicker inhalation b/c N₂O diffuses in then out of pulmonary capillaries and they collapse causing the concentration

Question 149

What are negatives of N₂O ?

Answer 149

- **N/V > 50% @ 0.5 MAC** - ↑ PVR - No surgeries with air filled spaces

Question 150

- N₂O is contraindicated in what patient population? Why?

Answer 150

- Neonates - May increase right-to-left shunt - Jeopardizes arterial oxygenation