Exam 2 Breathing Systems: Part 1 (6/20/24)

Question 1

Six Definitions of a Breathing System:

Answer 1

1. Receives gas mixture from the machine
2. Delivers gas to the patient
3. Removes CO2
4. Provides heating and humidification of the gas mixture
5. Allows spontaneous, assisted, or controlled respiration
6. Provides gas sampling, measures airway pressure, and monitors volume

Question 2

When gas is passing through a tube, where will the pressure be the highest?

Answer 2

the pressure at the inlet will be higher than at the outlet

Question 3

Describe Laminar Flow

Answer 3

Flow is smooth and orderly
Particles move parallel to the tube walls
Flow is fastest in the center where there is less friction

Question 4

True or False:
In laminar flow, the flow rate is the same across the diameter of the tube?

Answer 4

FALSE!

Flow is fastest in the center where there is less friction

Question 5

Which Law is used to describe Laminar Flow?

Answer 5

Poiseuille’s Law

Question 6

What type of flow is this?

Answer 6

Laminar Flow

Question 7

What type of flow?

Answer 7

Localized Turbulent Flow

Question 8

What type of flow is this?

Answer 8

Localized Turbulent Flow

Question 9

What type of flow is this?

Answer 9

Generalized Turbulent Flow

Question 10

What is the name given if the particles are moving across or opposite the general direction of flow ?

Answer 10

“Eddies”

Turbulent Flow

Question 11

In turbulent flow, is the flow rate the same or does it differ across the diameter of the tube?

Answer 11

Flow rate is same across diameter of tube

Question 12

Describe Generalized Turbulent Flow:

Answer 12

When the flow of gas through a tube exceeds the critical flow rate

Question 13

Describe Localized Turbulent Flow

Answer 13

Gas flow rate below the critical flow rate but encounters constrictions, curves, or valves

Question 14

To minimize resistance, gas-conducting pathways should have ___

Answer 14

• minimal length
• maximal internal diameter
• be without sharp curves or sudden changes in diameter

Question 15

Changes in resistance ___ changes in the work of breathing

Answer 15

Parallel

Question 16

What is one example of something that causes more resistance than the breathing system?

Answer 16

ET Tube

Question 17

What is compliance?
What does it measure?

Answer 17

Ratio of the change in volume over the change in pressure.

Measures Distensibility (ml/cm H2O)

Question 18

What are the most distensible components of our breathing system?

Answer 18

Breathing Tubes (Corrugated Tubing)
Reservoir Bags

Question 19

Compliance can help determine the patient’s ___.

Answer 19

Tidal Volume

Question 20

To inhale previously inspired gases from which CO2 may or may not have been removed:

Answer 20

Rebreathing

Question 21

What is Rebreathing influenced by?

Answer 21

• Fresh gas flow (High vs Low)
• Dead space
• Breathing system design (Semi, Closed, Open)

Question 22

Amount of rebreathing varies ___ with the ___.

Answer 22

Inversely
total FGF

Question 23

Will rebreathing occur or not?
Patient’s Minute ventilation is 5L/min and the FGF is 6L/min:

Answer 23

NO! The FGF is greater than the patient’s minute volume.

So long as exhaled gas is vented (not a closed system)

Question 24

Will rebreathing occur or not?
Patient’s Minute ventilation is 6L/min and the FGF is 6L/min:

Answer 24

NO! The FGF is equal to the patient’s minute volume.

So long as exhaled gas is vented (not a closed system)

Question 25

Will rebreathing occur or not?
Patient’s Minute ventilation is 6L/min and the FGF is 4L/min:

Answer 25

YES! The patient’s minute volume is greater than the FGF rate.

Question 26

Will rebreathing occur or not?
Patient’s tidal volume is 600 mls and has a respiratory rate of 10 breaths per minute. The FGF is at 5L/min.

Answer 26

YES! The patient’s minute volume is greater than the FGF rate.

Minute volume = (Vt) x (RR per min)

Question 27

True or False:
Some of the exhaled gases must be rebreathed to make up required volume

Answer 27

TRUE

Question 28

Define Apparatus Dead Space:
Examples?

Answer 28

Volume in a breathing system occupied by gases that are rebreathed without change in composition

Ex: ETT, Face Mask, anything distal to Y-Piece

Question 29

How can we decrease the amount of Apparatus Dead space?

Answer 29

by having inspiratory and expiratory limb separation as close to patient as possible

Question 30

Summation of anatomical and alveolar dead spaces equals…

Answer 30

Physiologic Dead Space

Question 31

Define Anatomical Dead space:

Answer 31

amount in the conducting airways; adds H2O vapor

Question 32

2 Things that rebreathing reduces:

Answer 32

1. Heat loss
2. Moisture loss

Question 33

Six desirable characteristics of a Breathing Circuit:

Answer 33

1. Low resistance to gas flow
2. Minimal Rebreathing
3. Removal of CO2 at the same rate of production
4. Rapid changes in delivered gas when required
5. Warmed humidification of inspired gas
6. Safe disposal of waste gases

Question 34

Describe an Open Circuit:
Example?

Answer 34

No reservoir bag and no rebreathing.

Ex. Nasal Cannula

Question 35

Patient’s minute ventilation is 4L/min and the FGF is 6L/min, what kind of circuit are we likely dealing with?

Answer 35

Semi-Open:

Reservoir bag but no rebreathing.

Question 36

Describe a Semi-Closed circuit:

Answer 36

Reservoir bag and partial rebreathing

Question 37

In a closed circuit, if the FGF is equal or less than the patient’s minute ventilation, what will occur?

Answer 37

Rebreathing

Question 38

A pop-off valve leading to the ____ is a required component to a breathing circuit.

Answer 38

scavenging system

Question 39

Where (in great detail) should the mask fit on a patient’s face?

Answer 39

Between the interpupillary line and in the groove between the mental process and the alveolar ridge

Question 40

Benefits to using connectors/adapters:

Answer 40

• Extends distance between patient and breathing system
• Change angle of connection
• Allow more flexibility/less kinking

Question 41

Disadvantages to using connectors/adapters:

Answer 41

• Increased resistance
• Increases dead space
• Additional locations for disconnects

Question 42

Which of the following is NOT used to describe the breathing tubing?
A. Large Bore
B. High Resistance
C. Corrugated
D. Plastic
E. Expandable

Answer 42

B. High Resistance

The breathing tubing should have low resistance and be somewhat distensible.

Question 43

Length and internal volume of breathing tubing:

Answer 43

1 meter in length
400-500 ml/m

Question 44

How is the flow through the breathing tubing classified?
Why?

Answer 44

Flow is always turbulent due to the corrugation!

Question 45

Generally, does adding longer tubes increase dead space?
Why or why not?

Answer 45

NO! Dead space is only from the Y piece to patient and not in the tubing itself because of the unidirectional gas flow valves.

Question 46

Is there ever an example in which the tubes could increase/contribute to dead space?

Answer 46

Yes, If the unidirectional Valves are closed/not working, they CAN contribute to dead space

Question 47

If the unidirectional valves are unable to close completely and rapidly with no backflow, what can occur?

Answer 47

An increase in Apparatus dead space

Question 48

The inspiratory unidirectional valve prevents:
The expiratory unidirectional valve prevents:

Answer 48

Inspiratory: Prevents backflow of exhaled gas

Expiratory: Prevents rebreathing

Question 49

Although the unidirectional valves can be mounted anywhere between the inspiratory and expiratory limbs, these are the typical places in which they are located:

Answer 49

• CO2 Absorber canister casing
• Fresh gas inflow site
• Pop-off (APL) valve

Question 50

5 requirements for the unidirectional valves:

Answer 50

1. Arrows or directional words
2. Hydrophobic
3. Must open and close appropriately
4. Clear dome
5. Must be placed between pt and reservoir bag

Question 51

Traditionally the reservoir bags are ___ for adults but can range from ___ to ___.

Answer 51

3L
0.5L - 6L

Question 52

Minimum and Maximum pressures for the breathing/reservoir bags.

Answer 52

Min: 30 cm H2O
Max: 40-60 cm H2O

Question 53

Describe the distending pressure difference between plastic bags and rubber bags:

Answer 53

Plastic bags have 2x the distending pressure as the rubber bags

Question 54

Describe some of the functions of the reservoir bag:

Answer 54

1. Reservoir for anesthetic gas and O2
2. A way to manual ventilate
3. Assists with spontaneous ventilation
4. Protection from excessive positive pressure

Question 55

Another name for the Gas inflow site is:

Answer 55

Fresh gas inlet

Question 56

Preferred location of the gas inflow site:

Answer 56

between CO2 absorbent and inspiratory valve

Question 57

The ___ permits gas to leave the circuit.

Answer 57

APL Valve or Pop-off valve

Question 58

Turning the APL valve in a clockwise motion will do what?

Answer 58

Increase the pressure

Question 59

How many clockwise turns does it take to fully close the APL valve if it is fully open?

Answer 59

1-2

Question 60

When is the APL valve open, closed or partially closed during spontaneous respiration?

Answer 60

Closed during Inspiration
Open during Expiration
Partially closed during inspiration with CPAP

Question 61

The APL valve will be partially open during both inspiration and expiration during what type of ventilation?

Answer 61

Assisted/Manual Ventilation

Question 62

APL use during mechanical ventilation?

Answer 62

Completely bypassed during both inspiration and expiration.

Question 63

Prior to using an absorber canister we need to make sure to…

Answer 63

Remove the wrap!!

Question 64

If we are needing to change out the absorber in the middle of a case, are we able to do that? Or do we have to wait until the end of the procedure?

Answer 64

You can change it in the middle of the case if necessary. The housing of the absorber incorporates valves that close when the canister is removed to prevent gas loss.

Question 65

What is the purpose of the side/center tube located in the absorbent cannister?

Answer 65

Returns the gas to the patient

Question 66

What kind of reaction occurs that causes our CO2 absorbers to become exhausted?

Answer 66

Exothermic Chemical reaction

Once exhausted, Carbonates are formed

Question 67

Describe the components of soda lime:
Which component prevents the absorbent from drying out?

Answer 67

• Calcium hydroxide (~80%)
• Sodium hydroxide and potassium hydroxide (~5%)
• Water (~15%)
• Small amounts of silica and clay (prevents drying out)

Question 68

When does the soda lime become exhausted?

Answer 68

when all hydroxides become carbonates

Question 69

Which components of the soda lime absorbent was thought to cause compound A and carbon monoxide?

Answer 69

Potassium and Sodium hydroxide

Sevo: Compound A / Des: Carbon Monoxide

Question 70

Soda lime can absorb ___ of its weight in ___.

Answer 70

19%
CO2

Question 71

100 g of Soda lime can absorb about ___.

Answer 71

26 L of CO2

Question 72

Where is the Lithium hydroxide absorbent used?

Answer 72

Submarines and Spacecrafts

Question 73

This absorbent does not have “regeneration”

What does this mean?

Answer 73

Litholyme

This means the pH indicators will not revert back to being colorless after becoming exhausted. (Soda lime has regeneration)

Question 74

Describe the Spira-Lith absorbent:

Answer 74

• Non-granular
• Larger surface area
• Reduced temperature production
• Longer Duration of use
• No color indicator

Question 75

Because the spira-lith has no color indicator, how would we know it is becoming exhausted?

Answer 75

Capnography

The patient’s baseline would continue to rise over time

Question 76

Which dye is the most common absorbent indicator?

Answer 76

Ethyl Violet

Question 77

As carbonates are forming, what color change occurs?

Answer 77

White to a blu-ish violet

Question 78

At what pH does the absorbent undergo the color change?

Answer 78

around 10.3 and below

Question 79

What is the purpose of the mesh located in CO₂ absorbents?

Answer 79

Maximize absorption and minimize resistance

Question 80

Channeling is when there are small passage-ways that allow gas to:
What does channeling decrease?

Answer 80

Flow through-low-resistance areas

Channeling decreases functional absorptive capacity

Question 81

Channeling can be minimized by:

Answer 81

• Circular baffles
• Placement for vertical flow
• Permanent mounting
• Prepackaged cylinders
• Avoiding overly tight packing

Question 82

Which of the following pictures is an example of channeling?

Answer 82

Question 83

Compound A formation theoretically occurs with these 4 things:

Answer 83

1. Low FGF
2. Increased absorbent temperature
3. Higher inspired sevoflurane concentrations
4. Dehydrated absorbent

Question 84

Desiccated strong base absorbents interact with ___.

Answer 84

Sevoflurane

Question 85

Select All that Apply:

A buildup of these 3 flammable degradation products within the absorber provide a basis for combustion.

A. Formaldehyde
B. Sulfuric Acid
C. Methanol
D. Polyvinylpyrrolidone
E. Silica
F. Formic Acid

Answer 85

A. Formaldehyde
C. Methanol
F. Formic Acid

Rationale: Buildup of high temperatures, flammable degradation products (formaldehyde, methanol, and formic acid), and oxygen or nitrous rich gases w/in the absorber all provide basis for combustion

Question 86

With which anesthetic gas was carbon monoxide most commonly occuring?

Answer 86

Desflurane

Question 87

Per the APSF recommendations, if we are using a 2 canister system…

Answer 87

Change them both

Question 88

True or False:
Compact canisters do not need as frequent changing as regular canisters.

Answer 88

FALSE