Breathing Systems Part II (Ericksen) Exam 2

Question 1

Which of the following are components of a Mapleson circuit? (Select 5)

A) Reservoir Bag
B) Corrugated Tubing
C) Oxygen Concentrator
D) Patient Connection
E) Inspiratory Valve
F) CO2 Absorber
G) Heat Exchanger
H) Fresh Gas Inlet
I) Expiratory Valve
J) APL Valve

Answer 1

A)Reservoir Bag
B)Corrugated Tubing
D) Patient Connection
H) Fresh Gas Inlet
J) APL Valve
Not all Maplesons have all these components

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Question 2

Mapleson circuits do not include a __________.

A. Reservoir Bag
B. CO2 Absorber
C. Corrugated Tubing
D. Patient Connection

Answer 2

B. CO2 Absorber

Question 3

Unlike more complex anesthesia circuits, Mapleson circuits lack __________ , which then negates the use of separate pathways for inspiratory and expiratory limbs.

A. Fresh Gas Inlets
B. Patient Connections
C. Reservoir Bags
D. Unidirectional Valves

Answer 3

D. Unidirectional Valves,

Question 4

Mapleson circuits are also known as __________ or __________.

A. Closed Circuits, Fresh Gas Flow Systems
B. High Flow Circuits, Flow-Controlled Breathing Systems
C. Carbon Dioxide Washout Circuits, Flow-Controlled Breathing Systems
D. Dual Limb Circuits, Low Flow Circle Systems

Answer 4

C. Carbon Dioxide Washout Circuits, Flow-Controlled Breathing Systems

Question 5

In the Magill’s System or Mapleson A circuit, the fresh gas flow (FGF) enters near the __________, which is opposite of the patient.

A. Adjustable Pressure-Limiting (APL) Valve
B. Reservoir Bag
C. Patient Connection
D. Corrugated Tubing

Answer 5

B. Reservoir Bag

Question 6

The APL valve in a Mapleson A circuit is positioned near the __________.

A. Fresh Gas Inlet
B. Reservoir Bag
C. Patient Connection
D. Overflow valve

Answer 6

C. Patient Connection

Question 7

Mapleson A circuits are the MOST efficient for __________ ventilation and worst for __________ ventilation.

A. Controlled, Spontaneous
B. Spontaneous, Controlled
C. Manual, Automatic
D. Spontaneous, Manual

Answer 7

B. Spontaneous, Controlled

Question 8

To prevent rebreathing in a Mapleson A circuit, the fresh gas flow must be ________ than or equal to the ____________ volume during spontaneous ventilation.

A. Greater/ Tidal
B. Greater/ Minute
C. Less/ Inspiratory
D. Less/ Minute

Answer 8

B. Greater/ Minute

Question 9

Which of the following statements are true about the Mapleson A circuit? (Select 2)

A. Requires less than 20L/min of minute ventilation to prevent rebreathing
B. Rebreathing during controlled ventilation occurs unless minute ventilation is very low
C. Rebreathing during controlled ventilation occurs unless FGF is very high
D. Requires more than 20L/min of FGF to prevent rebreathing

Answer 9

C. Rebreathing during controlled ventilation occurs unless FGF is very high
D. Requires more than 20L/min of FGF to prevent rebreathing - this is considered wasteful during controlled ventilation

Question 10

What gasses are represented by the blue, orange and red color?

Answer 10

Blue - Fresh Gas Flow
Orange - Dead Space Gas
Red - Alveolar Gas

Question 11

To prevent rebreathing, Fresh Gas Flow must be __________ than or equal to minute volume to prevent rebreathing during spontaneous breathing.

A) Greater
B) Less
C) Easier
D) Harder

Answer 11

A) Greater

*When the patient is expiring, a lot of gas goes out of the pop-off valve, but the FGF has to be very high >20L/min in order to help ventilate off that gas. *

When the patient is inspiring, they get a little bit of the dead space and alveolar gas with some FGF

Question 12

During controlled ventilation with a Mapleson A system, rebreathing occurs unless FGF is more than __________L/min

A) 10
B) 20
C) 30
D) 40

Answer 12

B) 20L/min
* A lot of this FGF is wasted through the APL valve during inspiration, so patient only gets a little bit of FGF with dead space and alveolar gas*

Question 13

In the Mapleson B circuit, the APL valve and fresh gas flow (FGF) are positioned near the __________.

A. Reservoir Bag
B. Patient
C. End of the system
D. Opposite the patient

Answer 13

B. Patient

Question 14

The reservoir bag in the Mapleson B system is located at the __________ of the system.

A. Beginning
B. Middle
C. End
D. Last Third

Answer 14

C. End

Question 15

Mapelson B
Much of the fresh gas flow (FGF) is vented through the APL valve during __________, making the system inefficient.

A. Inhalation
B. Exhalation
C. Both Inhalation and Exhalation
D. The Expiratory Pause

Answer 15

B. Exhalation

Question 16

For the Mapleson B system to be efficient, the fresh gas flow (FGF) should be ________ times the minute volume during spontaneous and controlled ventilation to prevent rebreathing.

A. 1x
B. 2x
C. 3x
D. 4x

Answer 16

B. 2x

Question 17

What is the Mapelson B considered, due to it being unrealistic and not used anymore.

A) Current
B) Modern
C) Obsolete
D) Updated

Answer 17

C) Obsolete

Question 18

In the Mapleson B, since the FGF is near the APL valve, gas will take the path of least resistance and a lot of FGF and ____________ gas will be vented out.

A) Dead Space
B) Fresh
C) Alveolar
D) Mixture

Answer 18

C) Alveolar
*Patient will get some FGF but not a lot *

Question 19

The Mapleson C circuit is identical to the Mapleson B circuit except that it omits the __________, making it similar to an AMBU bag.

A. APL Valve
B. Reservoir Bag
C. Corrugated Tubing
D. Fresh Gas Inlet

Answer 19

C. Corrugated Tubing
Not losing as much FGF and Alveolar Gas to atmosphere through the APL valve

Question 20

The Mapleson C circuit is almost as efficient as the Mapleson A circuit during __________ ventilation.

A. Controlled
B. Spontaneous
C. Manual
D. Assisted

Answer 20

B. Spontaneous

Question 21

In the Mapleson C system, the fresh gas flow (FGF) should be __________ times the minute volume.

A. 1x
B. 1.5x
C. 2x
D. 3x

Answer 21

C. 2x

Question 22

The Mapleson C system is commonly used for __________.

A. Routine Surgery
B. Emergency Resuscitation
C. Long-term Ventilation
D. Chronic Respiratory Failure

Answer 22

B. Emergency Resuscitation

EMERGEN - C

Looks like an AMBU bag

Question 23

The Mapleson C system’s efficiency during spontaneous ventilation is based on __________.

A. Fresh gas flow rate
B. Expiratory pause length
C. Position of the APL valve
D. Reservoir bag size

Answer 23

B. Expiratory pause length
As long as it is a minimal expiratory pause

Question 24

The Mapleson D circuit consists of a 3-way T-piece, which includes the patient connection, fresh gas inlet, and __________.

A. Reservoir Bag
B. Corrugated Tubing
C. APL Valve
D. CO2 Absorber

Answer 24

B. Corrugated Tubing

Question 25

In the Mapleson D system, the fresh gas flow (FGF) should be __________ times the minute ventilation.

A. 1x
B. 2x
C. 2 - 2.5x
D. 2.5 - 3x

Answer 25

C. 2 - 2.5x

Question 26

The Mapleson D system is considered the most efficient system for __________ ventilation.

A. Spontaneous
B. Manual
C. Controlled
D. Assisted

Answer 26

C. Controlled

Question 27

In the Bain modification of the Mapleson D circuit, the fresh gas flow is __________, inside the corrugated tubing.

A. Parallel
B. Coaxial
C. External
D. Intermittent

Answer 27

B. Coaxial
*With the fresh gas inlet its like an inspiratory limb with flow going towards the patient. *
Worry about disconnections, pay attention to kinks of inner hose

Question 28

In the Mapleson D system, __________ valves may be added to provide extra pressure and support during ventilation.
A. PEEP
B. APL
C. Inspiratory
D. Demand

Answer 28

A. PEEP

Question 29

During spontaneous ventilation with the Mapleson D system, the APL valve is __________.

A. Closed
B. Partially Closed
C. Open
D. Sealed

Answer 29

C. Open

Question 30

In the Mapleson D system, since the fresh gas flow (FGF) is closer to the patient, it is more likely to __________.

A. Get vented out
B. Go to the reservoir bag
C. Go to the patient
D. Mix with dead space gas

Answer 30

C. Go to the patient

Question 31

In the Mapleson D system during spontaneous ventilation, the patient receives a mix of __________ and __________ gas.

A. Dead Space, Fresh Gas Flow (FGF)
B. Alveolar, Dead Space
C. Fresh Gas Flow (FGF), Alveolar
D. CO2, O2

Answer 31

C. Fresh Gas Flow (FGF), Alveolar
Some of the alveolar is vented out through the APL valve, Dome of the dead space may get vented out or caught in reservoir bag

Question 32

With manually controlled ventilation in the Mapleson D system, the APL valve is __________ to increase pressure in the system.

A. Fully open
B. Partially closed
C. Fully closed
D. Slightly open

Answer 32

B. Partially closed

Question 33

When squeezing the reservoir bag during inspiration in manually controlled ventilation with the Mapleson D system, some of the __________ gas and some of the __________ gas get vented out of the Pop-off valve.

A. Dead Space, Alveolar
B. Fresh Gas Flow (FGF), Alveolar
C. Dead Space, Fresh Gas Flow (FGF)
D. Alveolar, O2

Answer 33

A. Dead Space, Alveolar

Question 34

In the Mapleson E (Ayre’s T-piece) system, the __________ attached to the T-piece forms the reservoir.

A. APL Valve
B. Reservoir Bag
C. Corrugated Tubing
D. Fresh Gas Inlet

Answer 34

C. Corrugated Tubing
End of system from the corrugated tubing is open to atmosphere

Question 35

The Mapleson E system does not include a __________ or __________, which decreases resistance in the system to the atmosphere.

A. Corrugated Tubing, Fresh Gas Inlet
B. Reservoir Bag, APL Valve
C. Patient Connection, Fresh Gas Flow
D. CO2 Absorber, Fresh Gas Inlet

Answer 35

B. Reservoir Bag, APL Valve
This decreases resistance in the system

Question 36

The Mapleson E system is preferred in __________ due to its decreased resistance.

A. Adults
B. Teenagers
C. Geriatrics
D. Pediatrics

Answer 36

D. Pediatrics

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Question 37

The Mapleson E system is used in __________ patients to deliver oxygen.

A. Controlled Ventilation
B. Manually Ventilated
C. Spontaneously Breathing
D. Mechanically Ventilated

Answer 37

C. Spontaneously Breathing
Can pinch the end of the corrugated tubing to do controlled ventilation. Pinch to increase pressure and assist in breathing and open the end for expiration. Hard to gauge pressure, monitor chest rise and fall to not put too much pressure .

Question 38

Why would we use the Mapleson E instead of simple mask, NRB or nasal cannula?

A) Delivers higher O2 flow rates
B) Delivers higher pressures
C) Delivers lower pressures
D) Removes more Deadspace gas

Answer 38

A) Delivers higher O2 flow rates
Cannot assist to take a DEEP breath

Question 39

The (Jackson Rees) Mapleson F system is a modification of the __________ system.

A. Mapleson A
B. Mapleson B
C. Mapleson D
D. Mapleson E

Answer 39

D. Mapleson E

Question 40

In the Mapleson F system, a __________ is added when compared to the Mepleson E system.

A. PEEP Valve
B. Reservoir Bag
C. CO2 Absorber
D. One-way Valve

Answer 40

B. Reservoir Bag (with a hole at the end)
Can see volume increasing and decreasing and helps moniotr RR

Question 41

The recommended fresh gas flow (FGF) for the Mapleson F system is __________ times the minute ventilation.

A. 1 - 1.5x
B. 1.5 - 2x
C. 2 - 2.5x
D. 2.5 - 3x

Answer 41

C. 2 - 2.5x

Question 42

The Mapleson F system is less likely to develop excessive pressure because it does not have a(n) __________.

A. Fresh Gas Inlet
B. Reservoir Bag
C. APL Valve
D. PEEP Valve

Answer 42

C. APL Valve
To increase pressure or assist in breathing, pinch off end at reservoir bag.

Question 43

Where would you see the Mapleson F used mostly?

A) OR
B) ICU
C) ER
D) All the above

Answer 43

See this for patient transport also ICU to OR or vice versa

Question 44

The Mapleson F system is functionally similar to the __________ system.

A. Mapleson A
B. Mapleson B
C. Mapleson D
D. Mapleson E

Answer 44

C. Mapleson D
Dead space gas is going out of the reservoir bag to the atmosphere through the hole at the end

Mapleson D does not have a hole in its reservoir bag like F…

Question 45

In the Mapleson F system, the patient primarily receives a mix of __________ and __________.

A. Dead Space gas, Fresh Gas Flow (FGF)
B. Alveolar gas, Dead Space gas
C. Fresh Gas Flow (FGF), Alveolar gas
D. CO2, O2

Answer 45

C. Fresh Gas Flow (FGF), Alveolar gas

Question 46

For spontaneous ventilation, which Mapleson system has the best efficiency?

A. Mapleson A
B. Mapleson B
C. Mapleson C
D. Mapleson D

Answer 46

A. Mapleson A

Question 47

For controlled ventilation, which Mapleson system is considered the worst in terms of efficiency?

A. Mapleson D
B. Mapleson E
C. Mapleson F
D. Mapleson A

Answer 47

D. Mapleson A

Question 48

Improved rebreathing efficiency in Mapleson circuits is due to the location of the __________ relative to FGF.

A. Reservoir Bag
B. Pop-off Valve
C. Patient Connection
D. Corrugated Tubing

Answer 48

B. Pop-off Valve

Question 49

In BC systems, significant amounts of fresh gas are vented through the pop-off valve at __________.

A. Start of Inspiration
B. End of expiration
C. Middle of inspiration
D. During the entire respiratory cycle

Answer 49

B. End of expiration

Question 50

In DEF systems, the fresh gas flow (FGF) drives exhaled alveolar gas __________ the patient.

A. Towards
B. Away from
C. Bypass
D. Under

Answer 50

B. Away from

Question 51

Which order for spontaneous ventilation is from best to worst?

A) DFE BC A
B) A DFE CB
C) A CB DFE
D) DEF BC A

Answer 51

B) A(best) DFE CB(worst)

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Question 52

Which order for controlled ventilation is from best to worst?

A) A DFE CB
B) A DEF CB
C) DFE CB A
D) DFE BC A

Answer 52

D) DFE(best) BC A(worst)

Dinosaurs Fly Every Blue Cloud Around

Question 53

One of the advantages of Mapleson circuits is that they are __________. Select 3

A. Expensive
B. Simple
C. Heavy
D. Lightweight
E. Difficult to assemble
F. Inexpensive

Answer 53

B. Simple
D. Lightweight
F. Inexpensive

Question 54

An advantage of Maplesons is changes in the fresh gas flow (FGF) composition result in __________ changes in the circuit.

A. Slow
B. Minimal
C. Rapid
D. Unnoticeable

Answer 54

C. Rapid

Question 55

An advantage of Mapleson circuits is that they have __________ resistance to gas flow.

A. High
B. Moderate
C. Low
D. Variable

Answer 55

C. Low

Question 56

One advantage of Mapleson circuits is that they produce no toxic products due to the lack of __________.

A. Potassium hydroxide
B. Volatile gasses
C. CO2 Absorbent
D. Corrugated Tubing

Answer 56

C. CO2 Absorbent

Question 57

Mapleson circuits do not degrade with __________.

A. Temperature changes
B. High pressure
C. Volatile Anesthetics
D. Long-term use

Answer 57

C. Volatile Anesthetics

Question 58

One disadvantage of Mapleson circuits is that they require __________ fresh gas flow (FGF).

A. Low
B. Moderate
C. High
D. Variable

Answer 58

C. High
remember to have a FULL O2 tank when transporting patient to and from OR

Question 59

The conservation of heat and humidity in Mapleson circuits is __________.

A. More efficient
B. Less efficient
C. Extremely efficient
D. Unchanged

Answer 59

B. Less efficient

Question 60

Scavenging is challenging in Mapleson circuits except in Mapelson D because the APL valve is located __________ from the patient.

A. Close
B. Directly
C. Away
D. Next to

Answer 60

C. Away

Question 61

The Mapleson circuit that only has the APL valve is closer to the reservoir bag?

A. Mapleson A
B. Mapleson B
C. Mapleson C
D. Mapleson D

Answer 61

D. Mapleson D

Question 62

Mapleson circuits are not suitable for patients with malignant hyperthermia (MH) because it may not be possible to increase FGF to remove excess __________.

A. O2
B. N2
C. CO2
D. H2O

Answer 62

C. CO2

Question 63

The Circle System allows for __________ flow.

A. Bidirectional
B. Unidirectional
C. Variable
D. Oscillatory

Answer 63

B. Unidirectional

Question 64

What is A?

Answer 64

Expiratory Valve

Question 65

What is B?

Answer 65

Pressure transducer port

Question 66

What is C?

Answer 66

Pressure Gauge

Question 67

What is D?

Answer 67

Bag-ventilator selector switch

Question 68

What is E?

Answer 68

APL valve

Question 69

What is F?

Answer 69

Scavenger outlet

Question 70

What is G?

Answer 70

Peep Valve

Question 71

What is H?

Answer 71

Reservoir Bag

Question 72

What is I?

Answer 72

Co2 absorber

Question 73

What is J?

Answer 73

Fresh gas inflow

Question 74

What is K?

Answer 74

Galvanic oxygen sensor

Question 75

What is L?

Answer 75

Inspiratory Valve

Question 76

What is M?

Answer 76

Gas sample port

Question 77

What is N?

Answer 77

Expiratory low sensor

Question 78

In a circle system, when the ventilator is off, you are ____________ it during spontaneous breathing.

A) Going through
B) Bypassing
C) Going under
D) Going around it

Answer 78

B) Bypassing… sailing on by

Question 79

True or False

During spontanous ventilation in a circle system, flows and gasses from the reservoir bag pass through the CO2 absorber during inspiration.

Answer 79

True

Spontaneous inspiration on circle system

Question 80

True or False

Fresh gas flow passes through the CO2 absorber during spontaneous exhalation into the reservoir bag, APL valve or scavenger outlet

Answer 80

True
If pressure gets too high in reservoir bag, flows get vented out the APL valve and scavenging system

Question 81

The extent of rebreathing and conservation of exhaled gases in the Circle System depends on __________.

A. Fresh Gas Flow (FGF)
B. CO2 Absorber
C. Placement of APL Valve
D. Reservoir Bag

Answer 81

A. Fresh Gas Flow (FGF)

Question 82

Higher fresh gas flow (FGF) results in __________ rebreathing and __________ waste gas.

A. Less, greater
B. More, less
C. Less, less
D. More, greater

Answer 82

A. Less, greater

Question 83

One of the rules to prevent rebreathing in a circle system, unidirectional valves must be located between the patient and the __________ on both the inspiratory and expiratory limbs.

A. Fresh Gas Inlet
B. Reservoir Bag
C. APL Valve
D. CO2 Absorber

Answer 83

B. Reservoir Bag

Question 84

One of the rules to prevent rebreathing in a circle system is that the fresh gas inflow cannot enter the circuit between the expiratory valve and the __________.

A. CO2 Absorber
B. Inspiratory Valve
C. APL Valve
D. Patient

Answer 84

D. Patient

Question 85

One of the rules to prevent rebreathing in a circle system is that the APL valve cannot be located between the patient and the __________ valve.

A. Expiratory
B. Inspiratory
C. Unidirectional
D. Fresh Gas

Answer 85

B. Inspiratory

Question 86

Which of the following best describes a semi-closed circle system?

A. No rebreathing occurs; all expired gas is vented.
B. Full rebreathing occurs; no expired gas is vented.
C. Partial rebreathing occurs; some waste flow is vented.
D. All expired gas is rebreathed without CO₂ removal.

Answer 86

C. Partial rebreathing occurs; some waste flow is vented.

Question 87

True or False

A Circle Systems that are Semi-closed is considered contemporary systems

Answer 87

True

Question 88

In a semi-closed circle system, what happens to the waste gas flow?

A. It is entirely rebreathed.
B. It is vented through APL valve
C. It is vented through the oxygen supply.
D. It is completely eliminated.

Answer 88

B. It is vented through APL or the waste gas valve of the ventilator.

Question 89

What is an example of the use of a semi-closed circle system?

A. High-flow anesthesia
B. Open anesthesia
C. Low-flow anesthesia
D. Closed anesthesia

Answer 89

C. Low-flow anesthesia

Question 90

In low-flow anesthesia, the fresh gas flow (FGF) is:

A. Greater than minute ventilation
B. Equal to minute ventilation
C. Less than minute ventilation
D. Not related to minute ventilation

Answer 90

C. Less than minute ventilation

Question 91

What percentage of expired gas is rebreathed after CO₂ removal in a semi-closed circle system?

A. 10%
B. 25%
C. 50%
D. 75%

Answer 91

C. 50%
*with lower flows, to make up the minute volume, it has to be rebreathed to make up the volume that is lost
*

Question 92

Which of the following best describes a semi-open circle system?
A. Complete rebreathing of gases
B. Non-rebreathing system
C. Complete breathing with minimal waste gas venting
D. Non-rebreathing system with no venting

Answer 92

B. Non-rebreathing system

Question 93

In a semi-open circle system, what characterizes the fresh gas flow (FGF)?

A. FGF is equal to minute ventilation
B. FGF is less than minute ventilation
C. FGF is higher with minimal rebreathing
D. FGF is negligible with complete rebreathing

Answer 93

C. FGF is higher with minimal rebreathing
Higher FGF with minimal rebreathing and more venting of waste gas

Question 94

Which of the following is an example of the use of a semi-open circle system? Select 3

A. Low-flow anesthesia
B. Post-operative ventilators
C. High-flow anesthesia
D. Open drop anesthesia
E. ICU ventilators
F. Scuba gear

Answer 94

B. Post-operative
E. ICU ventilators
F. Scuba gear… :)

Question 95

In a closed circle system, the rate of oxygen inflow:

A. Is higher than metabolic demand
B. Is less than metabolic demand
C. Exactly matches metabolic demand
D. Is independent of metabolic demand

Answer 95

C. Exactly matches metabolic demand

Question 96

What happens to waste gas in a closed circle system?

A. It is partially vented
B. It is fully vented
C. It is not vented at all
D. It is only vented during emergencies

Answer 96

C. It is not vented at all

Question 97

In a closed circle system, how are volatile anesthetics (VAs) added to the circuit?

A. They are not added
B. In gaseous form
C. In liquid form
D. Through a separate oxygen supply

Answer 97

C. In liquid form in precise amounts or through the vaporizer

Question 98

Which type of anesthesia is an example of a closed circle system?

A. High-flow anesthesia
B. Low- and minimal-flow anesthesia
C. Low flow anesthesia
D. Low- and high flow anesthesia

Answer 98

B. Low- and minimal-flow anesthesia

Question 99

Which of the following statements are true about the closed circle system? (Select 2)

A. Rebreathing is complete.
B. It is practical and commonly used.
C. Waste gas is vented completely
D. It is rarely done due to impracticality.
E. Oxygen inflow is less than metabolic demand.

Answer 99

A. Rebreathing is complete.

D. It is rarely done due to impracticality.

Question 100

Which of the following is an advantage of low-flow anesthesia?

A. Increased use of volatile anesthetics (VAs)
B. Difficulty in rapidly adjusting anesthetic depth
C. Improved temperature and humidity control
D. Increased environmental pollution 💀

Answer 100

C. Improved temperature and humidity control

Question 101

What is a disadvantage of low-flow anesthesia?

A. Decreased use of VAs
B. Easy to rapidly adjust anesthetic depth
C. Accumulation of unwanted exhaled gases
D. Reduced environmental pollution 🌼

Answer 101

C. Accumulation of unwanted exhaled gases

Question 102

One of the benefits of low-flow anesthesia includes:

A. Higher operating costs
B. Decreased use of volatile anesthetics
C. Increased waste gas ventilation
D. Complicated setup and operation

Answer 102

B. Decreased use of volatile anesthetics

Question 103

Which of the following is an advantage of low-flow anesthesia?

A. Difficulty in rapidly adjusting anesthetic depth
B. Accumulation of unwanted exhaled gases
C. VA degradation by-products
D. Reduced environmental pollution

Answer 103

D. Reduced environmental pollution

Question 104

Which of the following are disadvantages of low-flow anesthesia? (Select 3)

A. Difficulty in rapidly adjusting anesthetic depth
B. Improved temperature and humidity control
C. Possibility of accumulating unwanted exhaled gases
D. VA degradation by-products
E. Reduced environmental pollution

Answer 104

A. Difficulty in rapidly adjusting anesthetic depth
C. Possibility of accumulating unwanted exhaled gases ( CO, acetone, methane)
D. VA degradation by-products ( CO, Compound A)

Question 105

Which of the following are advantages of the circle system? (Select 2)

A. Low fresh gas flow (FGF) used
B. Complex design
C. Elimination of CO₂
D. CO or compound A production

Answer 105

A. Low fresh gas flow (FGF) can be used
C. Elimination of CO₂

Question 106

Which of the following are considered disadvantages of the circle system? (Select 2)

A. Prevention of OR pollution
B. Complex design
C. Conservation of moisture/heat/gases
D. Compromise of tidal volume (Vt) during controlled ventilation
E. Unstable inspired gas concentration

Answer 106

B. Complex design
D. May compromise tidal volume (Vt) during controlled ventilation
*Lost tidal volume in corrugated tubing *

Question 107

Which features contribute to the circle system’s effectiveness? (Select 3)

A. Relatively stable inspired gas concentration
B. Conservation of moisture/heat/gases
C. Prevention of OR pollution
D. Misconnections/disconnections

Answer 107

A. Relatively stable inspired gas concentration,
B. Conservation of moisture/heat/gases,
C. Prevention of OR pollution 🌸

What we give the patient is what is returned back. Maybe not 100%, but if there is a big discrepancy then investigate it

Question 108

What are some potential disadvantages with the use of the circle system? (Select 2)

A. Elimination of CO₂
B. Misconnections/disconnections
C. Relatively stable inspired gas concentration
D. CO or compound A

Answer 108

B. Misconnections/disconnections, (ASA Closed Claims Project)
D. CO or compound A

Question 109

Which components of the self-inflating manual resuscitator (AMBU) is used to increase oxygen pressure when needed? select 2

A. Self-expanding Bag
B. T-shaped non-rebreathing Valve
C. Oxygen reservoir
D. Pop-off valve

Answer 109

D. Pop-off valve
AKA APL valve
A. Self-expanding Bag

Question 110

Which of the following are components of a self-inflating manual resuscitator? (Select 3)

A. Self-expanding Bag
B. CO2 absorbent canister
C. Bag Inlet Valve
D. Oxygen concentrator
E. T-shaped non-rebreathing Valve

Answer 110

A. Self-expanding Bag,
C. Bag Inlet Valve
E. T-shaped non-rebreathing Valve,

*also includes pop off valve, excess oxygen venting valve, and oxygen reservoir

Question 111

Which of the following are components of a self-inflating manual resuscitator? (2)

A. Pop-off valve
B. L-shaped rebreathing valve
C. Excess Oxygen waste valve
D. Excess CO2 venting valve

Answer 111

A. Pop-off valve
C. Excess oxygen venting valve

Question 112

Which of the following is a primary use of a self-inflating manual resuscitator?

A. Continuous mechanical ventilation
B. Hand ventilation
C. Long-term oxygen therapy
D. Aerosol drug delivery

Answer 112

B. Hand ventilation in the absence of an oxygen or air source

Question 113

Self-inflating manual resuscitators are commonly used during:

A. Routine patient monitoring
B. Patient transport
C. Routine surgical procedures
D. Diagnostic imaging

Answer 113

B. Patient transport

Question 114

In emergency situations, a self-inflating manual resuscitator is essential for:

A. Measuring blood pressure
B. Delivering CPR
C. Administering intravenous fluids
D. Monitoring heart rate

Answer 114

B. Delivering CPR
ALWAYS have and AMBU bag in set up and attached to anesthesia machine!

Question 115

What can occur if the head is not positioned appropriately and oxygen is going down the esophagus when using a self-inflating manual resuscitator? Select 2

A. Hypoxia
B. Barotrauma
C. Hypercapnia
D. Hypocapnia
E. Gastric insufflation
F. Laryngospasm

Answer 115

B. Barotrauma
E. Gastric insufflation

Question 116

What is a significant concern related to the variation when using a self-inflating manual resuscitator?

A. Variations in RR, oxygen concentration and PEEP
B. Variations in tidal volume, oxygen concentration and PEEP
C. Variations in tidal volume, PIP, and PEEP
D. Variations in patient temperature

Answer 116

C. Variations in tidal volume, PIP, and PEEP

Question 117

What issue can nonrebreathing valves cause in a self-inflating manual resuscitator?

A. Generation of resistance
B. Increase in oxygen levels
C. Decrease in oxygen levels
D. Increase in carbon dioxide levels

Answer 117

A. Generation of resistance

Question 118

What is the primary purpose of using bacterial filters?

A. To enhance the smell of anesthetic gases
B. To prevent contamination or infection
C. To filter out solid particles from anesthesia gases
D. To cool the air before inhalation

Answer 118

B. To prevent contamination or infection by airborne diseases

Question 119

Which of the airborne diseases is mentioned in the slide that bacterial filters help prevent? (Select 2)

A. COVID
B. Malaria
C. M. Tuberculosis
D. Influenza

Answer 119

A. Covid
C. M. Tuberculosis

Question 120

PUI stands for _________, which indicates a person may be positive with an airborne disease.

Answer 120

Person under Investigation

Question 121

Where are bacterial filters placed in the anesthesia machine setup?

A. On the inspiratory limb
B. On the patient’s mask
C. On the oxygen tank
D. On the expiratory limb

Answer 121

D. On the expiratory limb

Question 122

What is a characteristic of a small-pore compact matrix in bacterial filters?

A. Low airflow resistance
B. High airflow resistance
C. No airflow resistance
D. Variable airflow resistance

Answer 122

B. High airflow resistance

Question 123

How is a small-pore compact matrix designed to pick up more pathogens?

A. It is less dense
B. It is pleated to create a smaller surface area
C. It is pleated to create a larger surface area
D. It is coated with antimicrobial agents

Answer 123

C. It is pleated to create a larger surface area

Question 124

What is a feature of a less dense, larger pore size arrangement in bacterial filters? (Select 2)
A. Increased airflow resistance
B. Smaller surface area
C. Less airflow resistance
D. Higher pathogen capture

Answer 124

B. Smaller surface area
C. Less airflow resistance
SMALLER surface area - picking up less pathogen

Question 125

Which of the following is a disadvantage of hydrophobic bacterial filters?

A. Decreased resistance
B. Increased efficiency
C. Increased resistance
D. Allows pathogen passage

Answer 125

C. Increased resistance
and Decreased Efficiency

Question 126

Where is the combination filter + HME placed?

A. At the patient’s mask
B. At the oxygen tank
C. At the Y-piece
D. On the expiratory limb

Answer 126

C. At the Y-piece
Inspiratory and Expiratory barrier

Question 127

Which of the following can cause obstruction in bacterial filters? Select 4

A. Dry air
B. Sputum
C. Edema fluid
D.Nebulized aerosols
E. Low humidity
F. Excessive oxygen flow
G. Malpositioning

Answer 127

B. Sputum
C. Edema fluid
D.Nebulized aerosols
G. Malpositioning

*If the filter gets wet, secretions, vomit, blood it gets even harder to get oxygen through. *

Question 128

Leakage in bacterial filters can occur due to issues with ________.

A. A crack in the patient mask
B. Damaged housing of a gas line filter
C. Loose connections
D. Overuse of the filter

Answer 128

B. Damaged housing of a gas line filter

Question 129

What is the recommended type of filter for COVID+ or PUI patients?

A. Carbon filter
B. Heat and moisture exchange filter
C. Pleated mechanical filter
D. Paper filter

Answer 129

B. Heat and moisture exchange filter HMEF
Electrostatic filter is acceptable

**

Question 130

When is the inspiratory limb filter recommended?

A. For all patients
B. When contaminated by a previous patient
C. After cleaning the maching
D. For pediatric patients

Answer 130

B. Only when the machine may have been contaminated by a previous patient

Question 131

What type of filter is preferred for the expiratory limb filter?

A. Electrostatic filter
B. Carbon filter
C. Pleated mechanical filter
D. Paper filter

Answer 131

C. Pleated mechanical filter

Question 132

True or False

An airway filter at the end of the Y-piece is required for Covid+ and PUI patients but optional for others

Answer 132

True

Question 133

What does humidity refer to in the context of humidification equipment?

A. Temperature of a gas
B. Amount of water vapor in a gas
C. Volume of gas
D. Pressure of gas

Answer 133

B. Amount of water vapor in a gas

Question 134

How is absolute humidity defined?

A. Percent saturation of water vapor at a particular temperature
B. Pressure exerted by water vapor in a gas mixture
C. Mass of water vapor present in gas in mg H₂O/L of gas
D. Volume of water vapor in a gas mixture in mg H₂O/L

Answer 134

C. Mass of water vapor present in gas in mg H₂O/L of gas

Question 135

What is relative humidity?

A. Percent saturation; amount of water vapor at a particular temperature
B. Mass of water vapor present in gas in mg H₂O/L of gas
C. Pressure exerted by water vapor in a gas mixture
D. Percent saturation; Amount of gas vapor in a water

Answer 135

A. Percent saturation; amount of water vapor at a particular temperature

Question 136

What does water vapor pressure refer to?

A. Amount of water vapor in a gas
B. Mass of water vapor present in gas in mg H₂O/L of gas
C. Percent saturation of water vapor at a particular temperature
D. Pressure exerted by water vapor in a gas mixture

Answer 136

D. Pressure exerted by water vapor in a gas mixture

Question 137

Where does maximal contact of inspired gas with large mucosal surface area occur?

A. In the trachea
B. In the nasal cavity
C. In the bronchi
D. In the alveoli

Answer 137

B. In the nasal cavity

Question 138

By which point has heating and humidification of inspired gas occurred?

A. Mid-trachea
B. Carina
C. Bronchi
D. Alveoli

Answer 138

A. Mid-trachea

Question 139

What is the temperature and absolute humidity of gas at the mid-trachea?

A. 37°C with an absolute humidity of 40-48 mg/L
B. 34°C with an absolute humidity of 34 to 38 mg/L
C. 30°C with an absolute humidity of 34 to 38 mg/L
D. 34°C with an absolute humidity of 40-48 mg/L

Answer 139

B. 34°C with an absolute humidity of 34 to 38 mg/L
95%-100% relative humidity

Question 140

As gas travels distally, it is headed to body temperature. What absolute humidity corresponds to 100% relative humidity at body temperature?

A. 30 mg/L
B. 38 mg/L
C. 44 mg/L
D. 50 mg/L

Answer 140

C. 44 mg/L
This is right at the carina. At 37C

Question 141

As gas travels distally, it is heated to body temperature: Select 3

A. Isothermic saturation boundary
B. Right at the carina
C. Is affected by the patient’s breathing rate
D. Occurs at the bronchioles
E. Results in a decrease in absolute humidity
F. Occurs in the nasal cavity
G. Can vary with external humidity and heating devices

Answer 141

A. Isothermic saturation boundary
B. Right at the carina
G. Can vary with external humidity and heating devices

Question 142

What happens to inspired gas in cold ambient temperatures?

A. It has high absolute humidity
B. It has little capacity to hold water vapor
C. It requires little heat energy to warm
D. It does not affect the upper airway

Answer 142

B. It has little capacity to hold water vapor

Question 143

In cold ambient temperatures, how does the upper airway respond?

A. It transfers small amounts of heat and moisture
B. It transfers moderate amounts of heat and moisture
C. It does not transfer any heat or moisture
D. It transfers large amounts of heat and moisture

Answer 143

D. It transfers large amounts of heat and moisture

Question 144

What is true about warm ambient temperatures?

A. Little heat energy is expended to warm inspired gases
B. The inspired gas has low absolute humidity
C. The upper airway transfers large amounts of heat and moisture
D. Lots of heat energy is expended to warm inspired gases

Answer 144

A. Little heat energy is expended to warm inspired gases

Question 145

Cool inspired gas may trigger bronchospasm, and this effect is especially noted in patients with ________ and ______. (Select 2)

A. Patients with COPD
B. Patients with diabestes
C. Patients with asthma
E. Patients with fibrosis
F. Patients with heart disease

Answer 145

A. Patients with COPD
C. Patients with asthma

Still poorly understood how it happens

Question 146

What is a consequence of underhumidification on the respiratory tract?

A. Increased secretion clearance
B. Secretions thin
C. Secretions thicken
D. Enhanced ciliary function

Answer 146

C. Secretions thicken
Decreases ciliary function

Question 147

What happens to surfactant activity during underhumidification?

A. Surfactant activity is enhanced
B. Surfactant production remains unchanged
C. Surfactant production increases
D. Surfactant activity is impaired

Answer 147

D. Surfactant activity is impaired
This makes opening and closing of the alveoli difficult

Question 148

Underhumidification can cause: Select 3

A. Mucosal susceptible to injury
B. Thinned secretions
C. Body heat loss
D. Enhanced surfactant activity
E. Tracheal tube obstruction

Answer 148

A. Mucosal susceptible to injury - friable
C. Body heat loss - use bear huggers and blankets
E. Tracheal tube obstruction - increases resistance and WOB from thickened secretions

Question 149

Why is it especially important to conserve humidity and heat in neonates and infants?

A. They have a lower metabolic rate
B. Their respiratory systems are fully developed
C. They are more susceptible to dehydration and heat loss
D. They produce more surfactant

Answer 149

C. They are more susceptible to dehydration and heat loss

Question 150

What is a consequence of overhumidification in the airway?

A. Increased mucosal viscosity
B. Reduced mucosal viscosity
C. Enhanced mucociliary transport
D. Decreased airway resistance

Answer 150

B. Reduced mucosal viscosity and risk of water intoxication and inefficient mucociliary transport

Question 151

What risks are associated with overhumidification in the airway?

A. Reduced airway resistance and improved ventilation, risk of pulmonary infection and V/Q mismatch
B. Reduced risk of pulmonary infection and V/Q mismatch, surfactant concentrated, atelectasis
C. Improved mucosal function and hydration, improved atelectasis
D. Increased airway resistance, risk of pulmonary infection, surfactant dilution, atelectasis, and V/Q mismatch

Answer 151

D. Airway resistance, risk of pulmonary infection, surfactant dilution, atelectasis, and V/Q mismatch

Question 152

How can overhumidification obstruct sensors?

A. By increasing sensor sensitivity
B. By improving sensor accuracy
C. By leading to inaccurate readings
D. By enhancing sensor function

Answer 152

C. ETCO2 sampling line can get condensation, leading to inaccurate readings

Question 153

What is the aim of humidification devices in the lower respiratory tract?

A. To decrease humidity levels
B. To reproduce more normal physiologic conditions
C. To reproduce more resistance in the airways
D. To add dead space in the airways

Answer 153

B. To reproduce more normal physiologic conditions
Do not burn the patient. Shouldn’t add resistance or dead space and infection

Question 154

How does a Heat and Moisture Exchanger (HME) function?

A. Actively heats and humidifies the air
B. Reduces airway humidity
C. Increases airway resistance
D. Passively humidifies the air

Answer 154

D. Passively humidifies the air

Question 155

How do heated humidifiers function?

A. Actively heat and humidify the air
B. Passively humidify the air
C. Decrease airway temperature
D. Increase airway resistance

Answer 155

A. Actively heat and humidify the air

Question 156

What does the Heat and Moisture Exchanger (HME) do with exhaled heat and water?

A. Discards it
B. Conserves it
C. Increases it
D. Decreases it

Answer 156

B. Conserves some of it and returns it to the patient

Question 157

What additional function does the HMEF provide?

A. Enhances airflow
B. Reduces airway resistance
C. Bacterial/viral filtration
D. Increases dead space

Answer 157

C. Bacterial/viral filtration *and prevention of inhalation of small particles HME-Filter *

Question 158

The HME is designed to be ________ with the exchange medium enclosed in plastic housing.

A. Reusable
B. Fragile
C. Disposable
D. Permanent

Answer 158

C. Disposable

Question 159

The HME is placed close to the patient, between the ________ and the proximal end of ETT or ________.

A. end of the ventilator/LMA
B. Inspiratory tube/ oxygen source
C. Y-piece/LMA
D. Oxygen source/LMA
E. Y-piece/HME filter

Answer 159

C. Y-piece/LMA
HME Can cause more dead space

Question 160

What is a potential effect of using an HME on ETCO₂ readings?

A. Low ETCO₂ readings
B. High ETCO₂ readings
C. No effect on ETCO₂ readings
D. Variable ETCO₂ readings

Answer 160

A. Low ETCO₂ readings

Question 161

How does an HME affect resistance and dead space in the circuit?

A. Decreases resistance and dead space
B. Increases resistance and dead space
C. No effect on resistance and dead space
D. Only affects resistance, not dead space

Answer 161

B. Increases resistance and dead space

Question 162

What factor may reduce the efficiency of an HME?

A. Small tidal volume (Vt)
B. High humidity levels
C. Large tidal volume (Vt)
D. Low resistance

Answer 162

C. Large tidal volume (Vt)
Hydrophobic models
*Larger models may reduce filtering *

Question 163

What type of barrier does a hygroscopic HME use?

A. Plastic membrane with moisture -retaining chemicals
B. Metal mesh coated with moisture -retaining chemicals
C. Paper with moisture-retaining chemicals
D. Fabric barrier with moisture -retaining chemicals

Answer 163

C. Paper or other fiber barrier coated with moisture-retaining chemicals
May have some electrostatic properties

Question 164

What is a characteristic of hygroscopic HMEs? Select 2

A. They do not absorb water
B. They release moisture in exhalation
C. They release water in inspiration
D. They have large pores
E. They absorb water in exhalation

Answer 164

C. They release water in inspiration
E. They absorb water in exhalation

Question 165

A potential drawback of hygroscopic HMEs is that they are prone to becoming ________, leading to increased inspiratory/expiratory resistance.

A. Hydrophilic
B. Unsaturated
C. Saturated
D. Unabsorbant

Answer 165

C. Saturated
Reduced heat and moisture retention - may need to change it out more

Question 166

What is an advantage of hydrophobic HMEs with pleated membranes and small pores?

A. They retain moisture better than hygroscopic HMEs
B. They are more efficient filters of pathogens
C. They are not prone to saturation
D. They do not increase resistance

Answer 166

B. They are more efficient filters of pathogens

Question 167

Where should a heated humidifier be placed?

A. In the expiratory limb
B. Downstream of the unidirectional valve in the inspiratory limb
C. Upstream of the unidirectional valve in the inspiratory limb
D. In the patient’s nostrils

Answer 167

B. Downstream of the unidirectional valve in the inspiratory limb

Question 168

Which type of patients are humidifiers used for? Select 2

A. Patients with hypertension
B. Neonates
C. Elderly
D. Patients with hypothermia
E. Patients with diabetes
F. Patients with fractures
G. Patients with hyperthermia

Answer 168

B. Neonates
D. Patients with hypothermia

Question 169

How does a bubble or cascade humidifier work?

A. By passing gas over a heated water reservoir
B. By heating water outside the vaporizer and then pumping it
C. By injecting water vapor and heat directly in the inspiratory limb
D. By absorbing water vapor in a bubble

Answer 169

D. By absorbing water vapor in a bubble
Active process

Question 170

How does a counter-flow humidifier function?

A. By passing gas over a heated water reservoir
B. By injecting water vapor and heat directly in the inspiratory limb
C. By heating water outside the vaporizer
D. By absorbing water vapor in a bubble

Answer 170

C. By heating water outside the vaporizer and then pumping it to the top of the vaporizer

Question 171

What is the role of inline humidifier?

A. They absorb water vapor in a bubble
B. They heat water outside the vaporizer and pump it to the top before the Y-piece
C. They inject water vapor and heat directly in the inspiratory limb before the Y-piece
D. They pass gas over a heated water reservoir

Answer 171

C. They are plastic capsules and inject water vapor and heat directly in the inspiratory limb before the Y-piece

Question 172

Why should water traps be changed frequently in humidifiers?

A. To increase the humidity of the gas
B. To decrease the risk of contamination
C. To maintain the temperature of the gas
D. To decrease the delivered volume

Answer 172

B. To decrease the risk of contamination and infection

Question 173

Condensation in a humidifier can decrease ________.

A. Delivered Vt
B. Oxygen concentration
C. Temperature of the gas
D. Risk of infection

Answer 173

A. Delivered Vt

Question 174

True or False

Humidifiers may be heated or unheated

Answer 174

True

Question 175

What is one of the main advantages of humidifiers?

A. They are more cost-effective than HME
B. They can deliver saturated gas at body temperature or higher
C. They are smaller and more portable than HME
D. They do not require electrical devices

Answer 175

B. They can deliver saturated gas at body temperature or higher

Question 176

What is a potential disadvantage of using humidifiers?

A. They cannot deliver gas at body temperature
B. They are less effective than HME
C. They are bulky and may have contamination issues
D. They are simpler to clean and maintain than HME

Answer 176

C. They are bulky and may have contamination issues
Water aspiration risk!!

Question 177

What is a risk associated with the use of humidifiers that involve heating devices?

A. Water aspiration
B. Electrical malfunction and/or thermal injury
C. Lower efficiency compared to HME
D. Reduced gas saturation

Answer 177

B. Electrical malfunction and/or thermal injury

Question 178

True or False

HME is higher cost than Humidifier

Answer 178

False

Question 179

Permanent electrical polarity increases ________ forces that hold organisms within the matrix.
A. Gravitational
B. Magnetic
C. Van der Waals
D. Electromagnetic

Answer 179

C. Van der Waals