Breathing Systems Part 1 (Ericksen) Exam 2

Question 1

Breathing Systems are defined as ____________ the gas mixture from the machine.

A) Delivering
B) Receiving
C) Removing
D) Allowing

Answer 1

B) Receives gas mixture from the machine
*Delivery of something via the circle system to the patient *

Question 2

Breathing Systems are defined as the process of ________ gas to the patient.

A) Monitoring
B) Recieving
C) Delivering
D) Removing

Answer 2

C) Delivering gas to the patient

Question 3

A primary function of the component of breathing systems is that it removes __________.

A) CO2
B) O2
C) CO
D) HCO3-

Answer 3

A) It removes CO2

Question 4

____________ and humidifying the gas mixture is a function of the breathing system.

A) Cooling
B) Conducts
C) Heating
D) Evaporating

Answer 4

C) Heating and humidifying of the gas mixture thats being delivered to the patient

Question 5

The functionality of a breathing system allows for spontaneous, ____________, or controlled respirations.
A) assisted
B) humidified
C) filtered
D) measured

Answer 5

A) assisted

Question 6

Breathing systems provide gas sampling, measure airway pressure, and __________ volume.
A) resist
B) increase
C) monitor
D) absorb

Answer 6

C) monitor

Question 7

When gas passes through a tube, the pressure at the outlet ( P1 ) will be ____________ than at the inlet (P2).

A) higher
B) the same
C) lower
D) fluctuating

Answer 7

C) lower
Outlet or P1 is where the tube is connected to the patient

Question 8

The drop in pressure (P2-P1) when gas passes through a tube is a measure of the __________ that must be overcome.

A) volume
B) temperature
C) resistance
D) velocity

Answer 8

C) resistance (R)

Question 9

Resistance (R) varies with the __________ of gas passing through per unit of time.

A) temperature
B) volume
C) pressure
D) composition

Answer 9

B) volume

If you add an extra tube, you add volume and increase resistance

Question 10

Which type of flow is described as smooth and orderly?

A) Turbulent
B) Laminar
C) Irregular
D) Mixed

Answer 10

B) Laminar

Question 11

Which type of flow is described as rough?

A) Turbulent
B) Laminar
C) Irregular
D) Mixed

Answer 11

A) Turbulent

Question 12

Flow types can change __________.

A) temperature
B) resistance
C) volume
D) pressure

Answer 12

B) resistance

Question 13

In laminar flow, particles move __________ to the tube walls.

A) perpendicular
B) randomly
C) parallel
D) prostrate

Answer 13

C) parallel
They move in the same direction, orderly, don’t bump into anything

Question 14

In laminar flow, the flow is fastest in the __________ of the tube where there is less friction.

A) center
B) near the walls
C) at the inlet
D) at the outlet

Answer 14

A) center

Question 15

Which law describes the relationship between pressure, flow, and resistance in laminar flow?

A) Newton’s Law
B) Boyle’s Law
C) Poiseuille’s Law
D) Ohm’s Law

Answer 15

C) Poiseuille’s Law
Parallel
Laminar

We don’t have to calculate this

Question 16

What letter(s) are considered Laminar flow?

Answer 16

A.

Question 17

What letters is considered Generalized Turbulent flow?

Answer 17

B.
Particles are bouncing against each other

Question 18

What letters correspond to Localized Turbulent flow?

Answer 18

C,D,E,F
Any difference in diameter, getting more narrow, bend or curve, another connection.
Laminar –> turbulent –> laminar

Question 19

Which of the following statements are true about turbulent flow? (Select 3)

A) Flow lines are parallel.
B) Flow lines are not parallel.
C) “Eddies” are composed of particles moving across the general direction of flow.
D) “Eddies” are composed of particles moving opposite the general direction of flow.
E) The flow rate is different across the diameter of the tube.

Answer 19

B) Flow lines are not parallel
C) “Eddies” are composed of particles moving across the general direction of flow
D) “Eddies” are composed of particles moving opposite the general direction of flow.

Question 20

Which of the following conditions can cause generalized turbulent flow?

A) When the flow of gas through a tube exceeds the critical flow rate.
B) When the flow of gas through a tube is below the critical flow rate.
C) The presence of constrictions, curves, or valves.
D) When the flow rate is different across the diameter of a tube

Answer 20

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

Question 21

Localized turbulent flow can occur under which of the following conditions? (Select 2)

A) Gas flow rate below the critical flow rate
B) When the flow of gas through a tube exceeds the critical flow rate.
C) Gas-conducting pathways are different across diameter of tube
D) Flow lines are parallel.
E) Gas flow rate encounters constrictions, curves, or valves.

Answer 21

A) Gas flow rate below the critical flow rate
E) Gas flow rate encounters constrictions, curves, or valves

Question 22

To minimize resistance in gas-conducting pathways, which of the following should be considered? (Select 3)

A) Maximal internal diameter of the tube.
B) Minimal internal diameter of the tube.
C) Pathways should be have sharp curves
D) Pathways should have minimal length.
E) Pathways should have maximal length
F) Pathways should be without sharp curves.

Answer 22

A) Maximal internal diameter
D) Minimal length
F) Without sharp curves

Ericksen-Minimize resistance in the system- ideal to have short, straight, wide and no curves

Like an Old Fashion drink glass :p

Question 23

Resistance imposes a strain with ventilatory modes where the patient must do part or all of the __________.

A) expiration
B) moving
C) work
D) inspiration

Answer 23

C) Work (inspiration and expiration)
If we are adding more things that the patient has to initiate breaths through, it makes it harder to breath through, increasing resistance

Question 24

Changes in resistance ____________changes in the work of breathing.

A) subdivide
B) separate
C) diverge
D) parallel

Answer 24

D) parallel
Increased WOB = Increased resistance

Question 25

The endotracheal tube (ETT) probably causes __________ resistance than the breathing system.

A) more
B) less
C) the same
D) no

Answer 25

A) more!
*It is one of the most narrow things going into the patient. Do not try to intubate yourself.. *

Question 26

How can you tell how much resistance is considered too much? (Select 2)

A) There is no common agreement
B) It is universally agreed upon
C) Watching flow-volume loops
D) Watching spirometry

Answer 26

A) There is no common agreement people just know if you keep adding things, it increases resistance
C) Watching flow-volume loops can help determine too much resistance

Looking at your system and looking at how your pt is breathing and the pressures will let you know how much resistance is there

Question 27

Compliance is the ratio of __________ to __________.

A) change in pressure; change in volume
B) change in volume; change in pressure
C) pressure; volume
D) volume; pressure

Answer 27

B) change in volume; change in pressure
How something easily expands and contracts

Question 28

Compliance measures __________.

A) resistance
B) distensibility
C) elasticity
D) viscosity

Answer 28

B) distensibility (mL/cmH20)

Question 29

Compliance helps determine __________.

A) respiratory rate
B) tidal volume (Vᵗ)
C) inspiratory time
D) expiratory time

Answer 29

B) tidal volume (Vᵗ)
Some components can stretch more to allow larger tidal volumes to be delivered to patient, like the resevoir bags and corrugated tubes.

Question 30

Which components are considered the most distensible in a breathing system?

A) Valves and connectors
B) Filters and humidifiers
C) Tubes and bags
D) Sensors and monitors

Answer 30

C) Breathing tubes and Reservoir bags

Breathing tubes that are corrugating

Question 31

Rebreathing is defined as the process of inhaling __________.

A) fresh gases only
B) previously inspired gases from which CO₂ may have been removed
C) previously inspired gases from which CO₂ may or may not have been removed
D) gases with increased oxygen concentration

Answer 31

C) previously inspired gases from which CO₂ may or may not have been removed

*Does not necessarliy mean CO2, can be any inhaled anesthetic gasses

If the CO2 scrubber/absorbant is exhausted then there is a higher chance of rebreathing CO2 d/t it not being removed*

Question 32

Which of the following factors influence rebreathing? (Select 3)

A) Fresh gas flow
B) Dead space
C) Type of anesthetic used
D) Breathing system design
E) Tidal volume

Answer 32

A) Fresh gas flow - high vs low flos
B) Dead space
D) Breathing system design - is it semi-closed/open, open or closed system

Question 33

The amount of rebreathing varies __________ with the total fresh gas flow (FGF).

A) directly
B) inversely
C) proportionally
D) exponentially

Answer 33

B) inversely

Question 34

If the volume of FGF supplied per minute is equal to or greater than the patient’s minute volume, __________ occurs.

A) rebreathing
B) no rebreathing
C) partial rebreathing
D) increased rebreathing

Answer 34

B) no rebreathing
Minute volume is the amount of gas inhaled or exhaled from a person’s lungs in one minute. Normal minute volume is 4-6L/min
**This is true as long as exhaled gas is VENTED, its leaving into the scavenging system. **

Question 35

Rebreathing occurs when the volume of FGF supplied per minute is __________ than the patient’s minute volume.

A) more
B) equal to
C) less
D) twice as much

Answer 35

C) less
Rebreathing occurs at low flows of air/oxygen at normal tidal volumes. Some of the inhaled gasses must be rebreathed to make up required volume

Question 36

Match the Dead Space to their definitions

Answer 36

1 - A
2 - C
3 - D
4 - B

Question 37

How can apparatus dead space be decreased?

A) By increasing the length of the breathing circuit
B) By adding more connectors to the breathing system
C) By having inspiratory and expiratory limb separation as close to the patient as possible
D) By having inspiratory and expiratory limb separation as further from the patient as possible

Answer 37

C) By having inspiratory and expiratory limb separation as close to the patient as possible apparatus dead space is decrease

**Apparatus dead space is ETT, facemask, anything distal from Y-piece. NOT insp/exp limbs.

Question 38

What is the composition of inspired gas during no rebreathing?

A) Identical to the fresh gas
B) Part fresh gas and part rebreathed gas
C) Entirely rebreathed gas
D) Mixed with atmospheric air

Answer 38

A) Identical to the fresh gas delivered by the anesthesia machine
*Anything that the patient is getting from the vent, nitrous, o2, oxygen, volatiles.. *

Question 39

What happens to the composition of inspired gas during rebreathing?

A) It is identical to the fresh gas
B) It is part fresh gas and part rebreathed gas
C) It is entirely rebreathed gas
D) It is mixed with atmospheric air

Answer 39

B) It is part fresh gas and part rebreathed gas

Question 40

Which of the following are effects of rebreathing? (Select 2)

A) Reduces heat loss from the patient
B) Reduces moisture loss from the patient
C) Increases heat loss from the patient
D) Increases moisture loss from the patient

Answer 40

A) Reduces heat loss from the patient
B) Reduces moisture loss from the patient

Question 41

Rebreathing can alter inspired gas tensions (partial pressures) by __________.

A) Increasing the inspired oxygen tension
B) Reducing the inspired oxygen tension
C) Reducing the inspired carbon dioxide tension
D) Increasing the inspired nitrogen tension

Answer 41

B) Reducing the inspired oxygen tension
*Think of a leak in the system, what we are putting in is not equaling what is coming out. There could be a leak and the machine and it isn’t alarming.

Question 42

How does altered inspired gas tensions affect the concentration of inhaled anesthetic agents?

A) It affects the concentration during induction and maintenance
B) It affects the concentration during induction and emergence
C) It has no effect on the concentration
D) It only affects concentrations during induction

Answer 42

B) It affects the concentration during induction and emergence
*During induction you want to see the same amount going in and coming out

During emergence, when you turn off the gas, you don’t want to see high numbers still with high flows, they should be blowing off the gas.*

Question 43

How does rebreathing affect the inspired carbon dioxide tension?
A) It decreases the inspired carbon dioxide tension
B) It has no effect on the inspired carbon dioxide tension
C) It increases the inspired carbon dioxide tension
D) It stabilizes the inspired carbon dioxide tension

Answer 43

C) It increases the inspired carbon dioxide tension

*Any rebreathing increases carbon dioxide. Alveolar dead space continuously increases, they are ventilating but not perfusing, the PaCO2 would increase and you will see a decrease in ETCO2.

Question 44

What contributes to the volume of airflow of inspired and expired gas? (Select 3)
A) Nitrous
B) Oxygen
C) Air
D) Volatile Gasses

Answer 44

A) Nitrous
B) Oxygen
C) Air
Ericksen- Volatiles do not contribute to the volume, they are just partial pressures

Question 45

Desirable characteristics of breathing circuit

A desirable characteristic of a breathing circuit is to have low __________ to gas flow.

A) resistance
B) pressure
C) volume
D) humidity

Answer 45

A) resistance

Question 46

Desirable characteristics of breathing circuit

Minimal __________ is important to prevent the patient from inhaling previously exhaled gases.

A) pressure
B) rebreathing
C) humidity
D) resistance

Answer 46

B) rebreathing

Question 47

Desirable characteristics of breathing circuit

The breathing circuit should ensure the removal of CO₂ at the rate of __________.

A) absorption
B) inhalation
C) production
D) exhalation

Answer 47

C) production

Question 48

Desirable characteristics of breathing circuit

The ability to make ________changes in delivered gas when required is a desirable characteristic.

A) secondary
B) rapid
C) undesirable
D) critical

Answer 48

B) Rapid
*Ericksen - we want to see these changes immediately. *

Question 49

Warmed __________ of inspired gas helps to maintain patient comfort and prevent respiratory complications.

A) filtration
B) ventilation
C) humidification
D) condensation

Answer 49

C) humidification

Question 50

Safe disposal of __________ gases is essential for maintaining a safe environment in the operating room.

A) inhaled
B) waste
C) fresh
D) mixed

Answer 50

B) waste
CO2 canisters and to the scavenging system, to reduce the amount of rebreathing going on

Question 51

Matching Classifications of Circuits to their definition

Answer 51

1 - b.
2 - a.
3 - c.
4 - d.

Question 52

Which type of circuit has no rebreathing or a reservoir bag and is open to atmosphere like a nasal cannula?

A) Open
B) Semi-open
C) Semi-closed
D) Closed

Answer 52

A) Open
No valves, open to atmosphere, no tubing. Patient is breathing in mixture of oxygen and RA, no rebreathing
Open drop ether, Ericksen is not that old

Question 53

In which type of circuit does partial rebreathing occur?

A) Open
B) Semi-open
C) Semi-closed
D) Closed

Answer 53

C) Semi-closed
*MOST commonly used, has a reservoir bag, tubing, circle system, APL valve.

Partial re-breathing, gasses have a way to escape. *

Question 54

Which type of circuit includes a reservoir bag but does not allow rebreathing?

A) Open
B) Semi-open
C) Semi-closed
D) Closed

Answer 54

B) Semi-open
Ericksen - resevoir bag and no rebreathing, HIGH fresh gas flow, higher than minute ventilation
“If our FGF is 6 and the minute ventilation 4L/min, then we have a semi-open system.”

Question 55

In a closed circuit, the presence of complete rebreathing depends on __________.

A) the type of gas used
B) the flow rate of fresh gas (FGF)
C) the size of the reservoir bag
D) the length of the circuit

Answer 55

B) the flow rate of fresh gas (FGF)
*Whatever is coming in is circulating and the patient is rebreathing it. LOW flow anesthesia, metabolic rate to the patient or lower.

If your FGF is equal or less than minute ventilation there is going to be rebreathing of insp/exp gasses.

What if our CO2 is exausted? Then yes, there is rebreathing.*

Question 56

Components of Anesthesia

A __________, LMA, or ETT is used to provide a secure airway for the patient.

A) facemask
B) reservoir bag
C) fresh gas inflow site
D) Y-piece

Answer 56

A) Facemask

Question 57

Components

__________ are used to deliver gas to and from the patient in the breathing circuit.

A) Respiratory valves
B) Carbon dioxide absorption canisters
C) Breathing tubing
D) Fresh gas inflow sites

Answer 57

C) Breathing tubing

Question 58

Components

__________ control the direction of gas flow within the breathing circuit.

A) Reservoir bags
B) Respiratory valves
C) Facemasks
D) Y-pieces

Answer 58

B) Respiratory valves

Question 59

Components

A __________ is used to store excess gas in the breathing circuit.

A) Y-piece
B) pop-off valve
C) reservoir bag
D) carbon dioxide absorption canister

Answer 59

C) reservoir bag

Question 60

Components

A __________ leading to scavenging helps to remove excess gases from the breathing circuit to maintain safety.

A) facemask
B) pop-off valve
C) Y-piece
D) fresh gas inflow site

Answer 60

B) pop-off valve

Question 61

Components

A __________ is used to remove carbon dioxide from the exhaled gases before they are rebreathed.

A) Y-piece
B) facemask
C) reservoir bag
D) carbon dioxide absorption canister

Answer 61

D) carbon dioxide absorption canister

Question 62

Components

A __________ with mask/tube connectors is used to connect the various components of the breathing circuit.

A) facemask
B) Y-piece
C) pop-off valve
D) fresh gas inflow site

Answer 62

B) Y-piece
*Tube connectors - Elbows, accordians like with trachs *

Question 63

An anesthesia mask is typically __________ to allow observation of the patient’s face and condition.

A) clear
B) opaque
C) colored
D) black

Answer 63

A) clear
They use to be black.

Question 64

The purpose of the pneumatic cushion in the mask’s cuff is to __________.

A) provide structural support
B) seal to the face
C) hold additional gas
D) attach other devices

Answer 64

B) seal to the face
*Inflatable or inflated cuff you can add or take away air to.

Question 65

The mask fits between the interpupillary line and in the groove between the __________ and the alveolar ridge.

A) nasal bridge
B) zygomatic arch
C) jawline
D) mental process

Answer 65

D) mental process
Should be between the interpupillary line and grooves of the mental process and alveolar ridges.. shouldn’t engulf the whole face

Question 66

Prongs on the anesthesia mask are used for attachment to __________.

A) the breathing tube
B) a rubber mask holder
C) the reservoir bag
D) the fresh gas inflow site

Answer 66

B) a rubber mask holder or head strap

Question 67

An anesthesia mask connects to the Y-piece or connector using a __________.

A) 15 mm male connection
B) 15 mm female connection
C) 22 mm male connection
D) 22 mm female connection

Answer 67

D) 22 mm female connection

Question 68

What is the primary purpose of connectors/adapters in a breathing circuit?

A) To monitor patient vitals
B) To join together two or more components
C) To increase the flow rate of gases
D) To measure gas composition

Answer 68

B) To join together two or more components

Question 69

One of the benefits of using connectors/adapters is that they __________.

A) extend the distance between the patient and the breathing system
B) decrease the flexibility of the breathing circuit
C) reduce the resistance in the circuit
D) increase the dead space in the circuit

Answer 69

A) extend the distance between the patient and the breathing system
Ericksen - if you need to turn the bed 90 or 180 for surgical positioning, allows you to add more length but it does increase deadspace

Question 70

Which of the following are disadvantages of using connectors/adapters? (Select 3)

A) Extends distance btween patient and breathing system
B) Increased dead space
C) Additional locations for disconnections
D) Reduced gas flow
E) Increased resistance

Answer 70

B) Increased dead space
C) Additional locations for disconnections
E) Increased resistance

Question 71

Which of the following are benefits of using connectors/adapters? (Select 4)

A) Extend the distance between patient and breathing system
B) Increase the resistance in the breathing circuit
C) Allow more flexibility
D) Change the angle of connection
E) Less kinking
F) Decreases resistance

Answer 71

A) Extend the distance between patient and breathing system
C) Allow more flexibility and less kinking
D) Change the angle of connection
E) less kinking

Question 72

Breathing tubing is typically __________ in length.

A) 0.5 meters
B) 1 meter
C) 1.5 meters
D) 2 meters

Answer 72

B) 1 meter

Question 73

The internal volume of breathing tubing is Large bore and typically __________ mL/m of length.

A) 100-200
B) 200-300
C) 400-500
D) 500-600

Answer 73

C) 400-500

Question 74

The flow through breathing tubing is always __________ due to corrugation.

A) laminar
B) turbulent
C) intermittent
D) steady

Answer 74

B) turbulent

Question 75

Breathing tubing is usually made of __________.

A) metal
B) rubber
C) plastic
D) glass

Answer 75

C) plastic
Pliable and expandable

Question 76

Expiratory and Inspiratory tubes do no contribute to dead space due to __________ gas flow.

A) bidirectional
B) turbulent
C) unidirectional
D) steady

Answer 76

C) unidirectional
As long as unidirectional valves are opening and closing properly and there is flow, the exp/insp tubing does not contribute to dead space

Question 77

Breathing tubing has __________ resistance and is somewhat distensible.

A) High
B) Moderate
C) Long
D) Low

Answer 77

D) low
Distensible or stretches out

Question 78

Two breathing tubes may be connected; longer tubes do not increase __________.

A) Dead space
B) Volume
C) Resistance
D) Direction

Answer 78

A) Dead space
*Dead space is only from the Y-piece to the patient. *

Question 79

Before use, pressure check circuits should be done to __________ cm H₂O.

A) 15
B) 20
C) 30
D) 45

Answer 79

C) 30 cmH20

Question 80

Which part of this tubing system would you have a mix of inspiration/expiration of gasses?

Answer 80

A. Bidirectional Gas Flow

Question 81

Which part(s) of the tubing system Is considered dead space?

Answer 81

A. Bidirectional gas flow
C. Y-piece
The picture above also shows dead space in the elbow, connector from elbow to ETT and the ETT tube. Anything DISTAL to the Y-piece is deadspace

Question 82

If the Inspiratory valve is open what part of the system should be closed?

Answer 82

D. Expiratory Limb
Whenever the Expiratory Limb is open, the inspiratory limb is closed.

Question 83

If flow is trying to go forward and the inspiratory valve is stuck, that part of the breathing system contributes to ________________.

A) Fresh Gas Flow
B) Expiratory Reserve
C) Deadspace
E) Bidirectional Gas flow

Answer 83

C) Deadspace

Question 84

The primary purpose of unidirectional valves in a breathing system is to __________.

A) control the temperature of the gas
B) direct respiratory gas flow
C) measure the pressure of the gas
D) increase the volume of the gas

Answer 84

B) direct respiratory gas flow in the correct direction

Question 85

Unidirectinal valves typically use disks with knife edges, rubber flaps, or __________ to control gas flow.

A) sleeves
B) turn dials
C) push buttons
D) relief valve

Answer 85

A) sleeves
rubber flaps and sleeves or are old school, mostly metal disks

Question 86

For optimal performance, unidirectional valves must open widely with __________.

A) high resistance
B) little pressure
C) a lot of pressure
D) rapid movement

Answer 86

B) little pressure

Question 87

To prevent backflow, unidirectional valves must __________.

A) open slowly and partially
B) close completely and rapidly
C) stay partially open at all times
D) close slowly with high resistance

Answer 87

B) close completely and rapidly
with NO backflow to prevent Apparatus dead space

Question 88

__________ resistance and __________ competence in unidirectional valves ensure that they move easily and don’t take a lot of pressure to lift the disk.

A. High, low
B. high, high
C. Low, low
D. Low, high

Answer 88

D. Low, high

Question 89

Which of the following statements are true about the unidirectional inspiratory valve? (Select 2)

A) Opens on inspiration
B) Closes on inspiration
C) Prevents backflow of exhaled gas
D) Prevents backflow of inhaled gas

Answer 89

A) Opens on inspiration
C) Prevents backflow of exhaled gas

Question 90

Which of the following statements are true about the expiratory valve? (Select 3)

A) Opens on inspiration
B) Closes on inspiration
C) Prevents rebreathing
D) Opens on exhalation

Answer 90

B) Closes on inspiration
C) Prevents rebreathing
D) Opens on exhalation

Question 91

Apparatus dead space can occur in which of the following locations? (Select 2)

A) Distal limb of the Y-connector
B) Tube/mask
C) CO₂ absorber canister
D) Fresh gas inflow site

Answer 91

A) Distal limb of the Y-connector
B) Tube/mask

Question 92

Where are unidirectional valves typically located in a breathing circuit?

A) Near CO₂ absorber canister casing
B) Fresh gas inflow site
C) Anywhere near the inspiratory limb
D) Anywhere near the expiratory limb
E) Pop off valves
F) All of the above

Answer 92

F) all of the above

Question 93

True or False

The arrow pointing away from the patient towards the ventilator is for inspiratory unidirectional valve?

Answer 93

False - Inspiratory arrow is pointed going towards the patient for the unidirectional valve

*Expiratory arrow for the unidirectional valve is pointing away from the patient towards the vent *

Question 94

Which features are necessary for the proper function of unidirectional valves? (3)

A. Transparent CO2 canister
B. Hydrophobic nature
C. Ability to open and close appropriately
D. Arrows or directional words
E. Connection to an external monitor

Answer 94

B. Hydrophobic nature
C. Ability to open and close appropriately
D. Arrows or directional words

Question 95

Unidirectional valves must meet certain criteria. Which of the following are true? (3)

A. Must have a clear dome.
B. Placed between the patient reservoir bag.
C. Must be manually operated.
D. Must be hydrophobic.
E. Must be connected to a humidifier.

Answer 95

A. They must have a clear dome.
B. They must be placed between the patient and the reservoir bag.
D. They must be hydrophobic.

Question 96

Breathing/Reservoir Bags are made out of non-slippery: (select 3)

A) Plastic
B) PVC
C) Rubber
D) Socks
E) Latex

Answer 96

A) Plastic
C) Rubber
E) Latex - phasing out of OR d/t allergies

Question 97

What shape are Breathing/Reservoir Bags designed to be for one-hand ventilation?
A. Spherical
B. Cubical
C. Ellipsoidal
D. Cylindrical

Answer 97

C. Ellipsoidal

Question 98

What is the traditional volume for adult Breathing/Reservoir Bags?
A. 1L
B. 2L
C. 3L
D. 6L

Answer 98

C. 3L
0.5L for peds and max of 6L

Question 99

What size female connector must Breathing/Reservoir Bags have on the neck?
A. 20 mm
B. 22 mm
C. 25 mm
D. 28 mm

Answer 99

B. 22mm female connector on the neck

Question 100

What is the minimum pressure required for Breathing/Reservoir Bags?
A. 20 cm H₂O
B. 25 cm H₂O
C. 30 cm H₂O
D. 35 cm H₂O

Answer 100

C. 30cm H20

Question 101

What is the maximum pressure range for Breathing/Reservoir Bags?
A. 30 - 40 cm H₂O
B. 35 - 55 cm H₂O
C. 40 - 60 cm H₂O
D. 45 - 65 cm H₂O

Answer 101

C. 40 - 60 cm H₂O

Question 102

How does the distending pressure of plastic Breathing/Reservoir Bags compare to rubber bags?
A. 0.5 times
B. Equal
C. 1.5 times
D. 2 times

Answer 102

D. 2 times

Question 103

What is true about reservoir bags and why we have them?
A) To give more pressure to help patients breath during light sedation
B) The bag offers pressure even if the patient is spontaneously breathing and the APL valve is open
C) So we can control the amount of pressure going into the patient with the APL valve closed a little bit
D) All of the Above

Answer 103

D) All of the above

*Ericksen - slide 30
Pt’s are breathing spontaneously we can add more pressure to help the patient breath. Close the APL valve a little bit and increase the pressure in our system. If we are doing assisted breathing, we can control the amount of pressure going into them.

If we open the APL valve, they are breathing on their own with a good tidal volume, the bag offers some pressure. Always some degree of pressure.*

Time stamp of 102:30, slide 30

Question 104

Which of the following is a function of a reservoir bag? (Select 2)
A. Reservoir for CO₂
B. Reservoir for anesthetic gases
C. Reservoir for O₂
D. Accurate measurement of tidal volume

Answer 104

B. Reservoir for anesthetic gases
C. Reservoir for O₂
*When we have air flow, the bag fills up and gets tight, the flow never stops filling up *

Question 105

How can a reservoir bag assist with ventilation?
A. By providing breathing stimulation
B. By decreasing spontaneous ventilation
C. By administering anesthetics
D. By means of manual ventilation

Answer 105

D. By means of manual ventilation
Squeeze the bag

Question 106

What type of ventilation can a reservoir bag assist with?
A. Spontaneous ventilation
B. Forced expiration
C. Active breathing
D. Decreasing respiration cycles

Answer 106

A. Spontaneous ventilation

Question 107

How does a reservoir bag help monitor ventilation?
A. By providing afferent feedback
B. By visual/tactile monitoring of ventilation
C. By recording data of ventilation
D. By estimating the respiration rate

Answer 107

B. By visual/tactile monitoring of ventilation

You can see the bag opening and closing, you can see pt. taking deep/shallow breaths. If the bag is quivering the patient is breathing rapid and shallow. Open APL valve and allows them to take deeper tidal volumes. Estimation of volume of ventilation

Question 108

How does a reservoir bag protect the patient during ventilation?
A. Filtering out impurities
B. Relieving negative pressure
C. Relief from excessive positive pressure
D. Cooling the exhaled air

Answer 108

C. Protecting from excessive positive pressure
*Some of the pressure will go into the bag and not stay in the patients lungs and relieve that pressure. *

Question 109

The gas inflow site has a _____.

A. fresh gas outlet
B. fresh gas inlet
C. CO₂ outlet
D. CO₂ inlet

Answer 109

B. fresh gas inlet

Question 110

The _________________ recieves gases and vapors from the machine and delivers the mixture via the fresh gas inlet to the circuit

A. oxygen tank
B. common gas inlet
C. common gas outlet
D. anesthetic reservoir

Answer 110

C. common gas outlet
Gases are delivered from the common gas outlet to the circuit

Question 111

In circle systems, the gas inflow site is located near the inspiratory unidirectional valve or _____.

A. expiratory unidirectional valve
B. CO₂ outlet
C. CO₂ absorbent canister housing
D. fresh gas inlet

Answer 111

C. CO₂ absorbent canister housing in circle systems

Question 112

The preferred location for the gas inflow site is between the CO₂ absorbent and _____.

A. expiratory valve
B. inspiratory valve
C. common gas outlet
D. fresh gas inlet

Answer 112

B. inspiratory valve

Question 113

The APL valve is also known as a the _____ valve.
A. check
B. pop-off
C. flow
D. release

Answer 113

B. pop-off
Old people call it this

Question 114

The APL valve permits gas to _____ the circuit.
A. enter
B. circulate within
C. leave
D. filter

Answer 114

C. leave

Question 115

The dome valve of the APL is loaded by a _____ and screw cap.
A. lever
B. spring
C. piston
D. diaphragm

Answer 115

B. spring

Question 116

The APL valve is ________-adjustable.
A. patient
B. time
C. user
D. temperature

Answer 116

C. User -we are twisting it

Question 117

The APL valve controls pressure in the _____ system.
A. oxygen supply
B. breathing
C. vacuum
D. anesthesia

Answer 117

B. breathing

Question 118

When the screw cap of the APL valve is tightened, _____ gas pressure is required to open it.
A. less
B. some
C. more
D. no

Answer 118

C. more
If its tightened clockwise we are closing it, reduces gas leaving and more pressure to open it. Increases pressure in the breathing system

Question 119

The APL valve releases gases to the _____ system.
A. heating
B. cooling
C. scavenging
D. filtering

Answer 119

C. scavenging

Question 120

In which direction should the APL valve be turned to increase pressure?

A. Counterclockwise
B. Clockwise
C. Perpindicular
D. Parallel

Answer 120

B. Clockwise - closing

Question 121

To decrease pressure, which motion should be applied to the APL valve?

A. Clockwise
B. Upward
C. Counterclockwise
D. Downward

Answer 121

C. Counterclockwise - opening

Question 122

How many clockwise turns does it take to move the APL valve from fully open to fully closed?

A. 0.5 to 1 turn
B. 1 to 2 turns
C. 2 to 3 turns
D. 3 to 4 turns

Answer 122

B. 1 to 2 turns

Question 123

What must be present to indicate the direction to close the APL valve?

A. An arrow
B. An circle
C. A square
D. A sound

Answer 123

B. An arrow

Question 124

During spontaneous respiration, the Check Valve disc is _____ during inspiration.
A. Open
B. Closed
C. Partially open
D. Bypassed

Answer 124

B. Closed

Question 125

During mechanical ventilation, the APL valve is _____.
A. Open
B. Closed
C. Partially open
D. Bypassed

Answer 125

D. Bypassed
vent is doing the work

Question 126

During assisted/manual ventilation, the APL valve is _____ during expiration.
A. Open
B. Closed
C. Partially open
D. Bypassed

Answer 126

C. Partially open
Excess is diverted

Question 127

Matching

Matching

Answer 127

Question 128

What feature of the absorber canister allows for visual inspection?
A. Opaque sides
B. Transparent sides
C. Colored sides
D. Reflective sides

Answer 128

B. Transparent sides

Question 129

How many absorber canisters can be used in a series (stacked)?
A. Only one
B. Two or three
C. One or two
D. Four or five

Answer 129

C. one or two

Question 130

What must be done to the absorber canister before use?
A. Shake it
B. Warm it
C. Remove the wrap
D. Top it off

Answer 130

C. Remove the wrap!!!!
Remove it. Remove it. Remove it

…did you remove it

Question 131

What is the function of the side/center tube in the absorber canister?
A. To filter the gas
B. To humidify the gas
C. To heat the gas
D. To return the gas to the patient

Answer 131

D. To return the gas to the patient

Question 132

True or False

Absorber Cansiter Housing - Incorporates valves that open when the canister is removed to prevent gas loss

Answer 132

FALSE
Incorporates valves that close when the canister is removed to prevent gas loss

You can change this in the middle of a case

Question 133

When were canisters with absorbent invented?
A) 1924
B) 1942
C) 1934
D) 1925

Answer 133

A) 1924

Question 134

What is the initial reaction that occurs with carbon dioxide and water in the absorbent?
A. Formation of a solid
B. Formation of an aqueous solution
C. Formation of a gas
D. No reaction occurs

Answer 134

B. Formation of an aqueous solution

Question 135

What type of reaction is involved when carbon dioxide combines with hydroxides in the absorbent?
A. Endothermic reaction
B. Exothermic reaction
C. Neutral reaction
D. No reaction

Answer 135

B. Exothermic reaction

Question 136

Which compounds does carbon dioxide combine with to form a carbonate in the absorbent?
A. Sodium, potassium, lithium, or calcium
B. Magnesium, aluminum, or iron
C. Sodium chloride, potassium chloride, lithium chloride, calcium chloride
D. Water, oxygen, and nitrogen

Answer 136

A. Sodium, potassium, lithium, or calcium
all hydroxides

Question 137

What happens to the absorbent when it is exhausted?
A. It remains unchanged
B. It turns into carbonates
C. It dissolves completely
D. It releases oxygen

Answer 137

B. It turns into carbonates
Any hydroxides, they interact with CO2 that is passing through to form a exothermic reaction and that is what leads to exhausting absorbent.

*When absorbent is exhausted it turns into carbonates, it changes the color from white to purple. *

Question 138

Why do newer absorbents have less than 2% sodium or potassium hydroxide, or none at all?
A. To reduce the cost of production
B. To prevent toxic reactions to humans
C. To increase the absorbent’s effectiveness
D. To enhance the color-changing property

Answer 138

B. To prevent toxic reactions to humans when using sevoflurane and desflurane

Question 139

Which of the following are components of soda lime absorbents? (Select 5)
A. Calcium hydroxide
B. Sodium hydroxide
C. Potassium hydroxide
D. Lithium hydroxide
E. Water
F. Large amounts of silica and clay
G. Small amounts of silica and clay

Answer 139

A. Calcium hydroxide
B. Sodium hydroxide
C. Potassium hydroxide
E. Water
G. Small amounts of silica and clay
Silica and clay keep it from hardening and drying out.

Absorbent becomes exhaused when all the hydroxides become carbonates

Question 140

Soda lime can absorb ____% of its weight in CO₂.
A. 15%
B. 19%
C. 25%
D. 30%

Answer 140

B. 19%

Question 141

100 g of soda lime can absorb approximately ____ L of CO₂.
A. 20 L
B. 25 L
C. 26 L
D. 30 L

Answer 141

C. 26 L CO2
this is a lot it can scrub

Question 142

What is the approximate percentage of calcium hydroxide in soda lime?
A. 60%
B. 70%
C. 80%
D. 90%

Answer 142

C. 80%

Question 143

What is the approximate percentage of sodium hydroxide and potassium hydroxide in soda lime?
A. 3%
B. 5%
C. 7%
D. 10%

Answer 143

B. 5%
Leads to Compound A
CO
Destruction of inhaled gases

Question 144

What is the approximate percentage of water in soda lime?
A. 10%
B. 12%
C. 15%
D. 20%

Answer 144

C. 15%

Question 145

Which of the following are components of calcium hydroxide lime absorbents? (Select 5)

A. Calcium hydroxide (70%)
B. Calcium chloride (0.7%)
C. Calcium sulfate (0.7%)
D. Sodium hydroxide (0.7%)
E. Water (14.5%)
F. Polyvinylpyrrolidone (0.7%)
G. Potassium hydroxide (14.5%)

Answer 145

A. Calcium hydroxide (70%)
B. Calcium chloride (0.7%)
C. Calcium sulfate (0.7%)
E. Water (14.5%)
F. Polyvinylpyrrolidone (0.7%)..say that 3 times fast

Question 146

Calcium hydroxide lime is the same thing as _______.
A. Soda lime
B. Amsorb
C. Baralyme
D. Litholyme

Answer 146

B. Amsorb

Question 147

What are the three things are not a concern with Calcium hydroxide lime?

A) Compound A
B) CO production
C) Endothermic reactions
D) Formation of water
E) Destruction of inhaled gases

Answer 147

A. Compound A
B. CO
E. Destruction of inhaled gases

Question 148

Which of the following statements are true about lithium hydroxide (LiOH) as an absorbent? (Select 3)

A. Reacts with CO₂ to form carbonate
B. Has less CO₂ absorption capacity
C. Used in submarines
D. Used in spacecrafts

Answer 148

A. Reacts with CO₂ to form carbonate
C. Used in submarines
D. Used in spacecrafts

Question 149

What is one of the benefits of using lithium hydroxide as an absorbent?
A. Less CO₂ absorption capacity
B. More CO₂ absorption capacity
C. Reacts with CO₂ to form water
D. Interacts with volatile gasses

Answer 149

B. More CO₂ absorption capacity

Question 150

What is one reason lithium hydroxide is preferred for CO₂ absorption despite its high cost?
A. It interacts with volatile gases
B. It is inexpensive
C. It does not interact with volatile gases
D. It is easy to produce

Answer 150

C. It does not interact with volatile gases
Due to NOT having KOH and NaOH

Question 151

What is a safety concern when handling lithium hydroxide?
A. It is non-reactive
B. It causes burns
C. It causes bleeding gums
D. It causes fingernails to fall off

Answer 151

B. It causes burns to skin, eyes, and lungs

Question 152

Litholyme uses a ________ catalyst and does not react with inhaled anesthetic agents.
A. Sodium chloride
B. Lithium chloride
C. Potassium chloride
D. Calcium chloride

Answer 152

B. Lithium chloride
NO KOH and NaOH

Question 153

Litholyme contains no activators or strong bases, which means it does not form ________ and ________.
A. Compound A; oxygen
B. Carbon dioxide; oxygen
C. Compound A; CO
D. Lithium; carbonate

Answer 153

Compound A; CO

Question 154

Litholyme has no regeneration, meaning pH indicators do not become ________.
A. Red
B. Purple
C. Colorless
D. Green

Answer 154

C. Colorless
Its going to change to purple and not change back to colorless

Question 155

Litholyme has lower ________ reactivity, which reduces the risk of fire and economic/environmental impact.
A. Endothermic
B. Exothermic
C. Neutral
D. Photochemical

Answer 155

B. Exothermic

Question 156

Spira-Lith uses anhydrous ______ powder within a nongranular partially hydrated polymer sheet.
A. NaOH
B. KOH
C. LiOH
D. CaOH

Answer 156

C. LiOH Lithium Hydroxide

Question 157

What are some advantages of Spira-Lith? (Select 3)

A. Larger surface area
B. Longer duration of use
C. Contains color indicator
D. Cost-effective
E. Turns from white to violet
F. Requires monitoring inspired CO₂

Answer 157

A. Larger surface area for reaction
B. Longer duration of use
D. Cost-effective

Disadvantage–>Requires monitoring inspired CO₂ (no color indicator) NO color change

Question 158

Which of the following are features of Spira-Lith? Select 4

A. Anhydrous LiOH powder
B. Nongranular
C. Small surface area for reaction
D. Contains activators or strong bases
E. Reduced temperature production
F. Partially hydrated polymer sheet

Answer 158

A. Anhydrous LiOH powder
B. Nongranular
E. Reduced temperature production
F. Partially hydrated polymer sheet

Question 159

What is the most common dye used as an absorbent indicator?
A. Ethyl orange
B. Cresyl yellow
C. Ethyl violet
D. Methyl red

Answer 159

C. Ethyl violet
Other colors are Ethyl orange to yellow
and Red to Cresyl yellow.

Question 160

What happens to the pH during carbonate formation in absorbents?
A. pH becomes more alkaline
B. pH becomes less alkaline
C. pH remains neutral
D. pH becomes acidic

Answer 160

B. pH becomes less alkaline
white to blue/ethyl violet

Question 161

What color change does an exhausted absorbent undergo when the pH is <10.3?
A. Blue to green
B. Yellow to orange
C. White to purple
D. There is no color change

Answer 161

C. White to purple <10.3
pH >10.3 is colorless

Question 162

What can cause the bleaching of the absorbent indicator?
A. Sunlight
B. Fluorescent lights
C. UV light
D. Incandescent lights

Answer 162

B. Bright Fluorescent lights for a long time.
Not a problem in the operating room

Question 163

Which of the following are factors that reflect the reliability of absorbent indicators? Select 3.

A. Regeneration
B. Color fading
C. Temperature changes
D. Pressure changes
E. Capnometry

Answer 163

A. Regeneration
B. Color fading
E. Capnometry
If you are unsure the absorbent canister is exhausted, dried out or dessicated, change it out. Another way to know is if you see increase in ETCo2.

Question 164

What is the typical mesh (granular) size range used in the canister?
A. 1 – 3
B. 2 – 6
C. 4 – 8
D. 6 – 10

Answer 164

C. 4 – 8 mesh size
Granular size - grapenuts

Question 165

What is the primary goal of selecting the appropriate mesh size in the canister?
A. Minimize absorption and maximize resistance
B. Maximize absorption and minimize resistance
C. Minimize both absorption and resistance
D. Maximize both absorption and resistance

Answer 165

B. Maximize absorption and minimize resistance

Question 166

What is the texture of the surface described in the mesh?
A. Smooth and regular
B. Rough and irregular
C. Sticky and uneven
D. Soft and pliable

Answer 166

B. Rough and irregular, like grape nuts

Question 167

What proportion of the canister volume is gas?
A. One-third
B. One-fourth
C. One-fifth
D. Half

Answer 167

D. Half

Question 168

What effect does excess liquid water within the canister have?
A. Increases surface area and efficiency of CO₂ absorption
B. Decreases surface area and efficiency of CO₂ absorption
C. Has no effect on surface area and efficiency of CO₂ absorption
D. Enhances resistance but does not affect absorption

Answer 168

B. Decreases surface area and efficiency of CO₂ absorption

Question 169

What does channeling refer to in the context of the canister?
A. Large passageways allowing gas to flow through high-resistance areas
B. Small passageways allowing gas to flow through low-resistance areas
C. Large passageways allowing gas to flow through low-resistance areas
D. Small passageways allowing gas to flow through high-resistance areas

Answer 169

B. Small passageways allowing gas to flow through low-resistance areas
Decreases functional absorptive capacity

Question 170

Which picture is an example of Channeling?

Answer 170

E. Channeling. Path of least resistance

Question 171

Which of the following can help minimize channeling in the canister?
A. Circular baffles
B. Horizontal flow placement
C. Temporary mounting
D. Loose packing

Answer 171

A. Circular baffles
Round circular tube that goes through or on the side of the canister

Question 172

Which of the following strategies help minimize channeling in the canister? (Select 4)

A. Oblong baffles
B. Placement for vertical flow
C. Permanent mounting
D. Prepackaged cylinders
E. Avoiding overly tight packing
F. Temporary mounting
E. Avoiding overly loose packing

Answer 172

B. Placement for vertical flow
C. Permanent mounting - can move it
D. Prepackaged cylinders - remove the plastic
E. Avoiding overly tight packing - compacting

Question 173

What leads to the formation of Compound A?
A. Decomposition of nitrous oxide
B. Decomposition of sevoflurane
C. Decomposition of isoflurane
D. Decomposition of halothane

Answer 173

B. Decomposition of sevoflurane

Question 174

Compound A is possibly ______ in humans.
A. Hepatotoxic
B. Cardiotoxic
C. Neurotoxic
D. Nephrotoxic

Answer 174

D. Nephrotoxic -in rats mostly

Question 175

Which of the following factors contribute to the formation of Compound A? Select 4

A. Endothermic reactions
B. High FGF
C. Increased absorbent temperature
D. Higher inspired sevoflurane
E. Dehydrated absorbent
F. Use of KOH and KCL
G. Low FGF

Answer 175

C. Increased absorbent temperature - carbonate formation
D. Higher inspired sevoflurane concentrations
E. Dehydrated absorbent
G. Low FGF

Happens with KOH and NaOH

Question 176

What type of absorbent condition leads to carbon monoxide production?
A. Wet absorbent
B. Dry absorbent
C. Acidic absorbent
D. Neutral absorbent

Answer 176

B. Dry absorbent

Question 177

Carboxyhemoglobin levels greater than _______ can cause a “dip in pulse ox.”
A. 15%
B. 25%
C. 35%
D. 45%

Answer 177

C. >35%

Question 178

Which monitoring devices do not pick up carbon monoxide production effectively? (Select 2)
A. Co-oximetry
B. Pulse oximetry
C. Capnography
D. Blood gas analyzers
E. IR gas monitors

Answer 178

B. Pulse oximetry
E. IR gas monitors

Co-oximetry picks up this, but only if you have a fancy OR

Question 179

When are the highest levels of carbon monoxide typically observed?
A. End of the day
B. Middle of the week
C. Monday, 1st case
D. During routine maintenance

Answer 179

C. “Monday, 1st case”
*Leaving the flows up, drying out absorbent, not sure if the absorbent is exhausted. *

Question 180

Which anesthetic gas is associated with the highest levels of carbon monoxide production?
A. Sevoflurane
B. Halothane
C. Isoflurane
D. Desflurane

Answer 180

D. Desflurane
*Desflurane ≥ enflurane > isoflurane > halothane > sevoflurane
*

Question 181

Which factors contribute to the production of carbon monoxide in the anesthetic circuit? Select 3

A. Decreased concentration of gasses
B. Increased temperatures
C. Low FGF rates
D. Strong base absorbents
E. High FGF rates
F. Hydrated absorbent

Answer 181

B. Increased temperatures
C. Low FGF rates
D. Strong base absorbents

Also Increased concentrations of anesthetic gasses

Question 182

What type of reactions can lead to fires and explosions in absorbents?
A. Endothermic reactions
B. Exothermic reactions
C. Neutral reactions
D. Photochemical reactions

Answer 182

B. Exothermic reactions

Question 183

Which types of absorbents interact with sevoflurane to produce heat?
A. Acidic absorbents
B. Neutral absorbents
C. Desiccated strong base absorbents
D. Hydrated weak base absorbents

Answer 183

C. Desiccated strong base absorbents

Question 184

What are examples of desiccated strong base absorbents?
A. Baralyme and anhydrous LiOH
B. Sodium hydroxide and calcium hydroxide
C. Potassium hydroxide and magnesium hydroxide
D. Silica gel and activated charcoal

Answer 184

A. Baralyme and anhydrous LiOH

Question 185

At what temperature can absorbents exceed, leading to fire in some breathing circuits?
A. 100 degrees Celsius (212 degrees Fahrenheit)
B. 150 degrees Celsius (302 degrees Fahrenheit)
C. 200 degrees Celsius (392 degrees Fahrenheit)
D. 250 degrees Celsius (392 degrees Fahrenheit)

Answer 185

C. 200 degrees Celsius (392 degrees Fahrenheit)

Question 186

What flammable degradation products can buildup at high temperatures within the absorber?
A. Formaldehyde, methanol, and formic acid
B. Carbon dioxide, Tapatio, and methane
C. Ammonia, Absorbic Acid, and hydrogen
D. Formaldehyde, Carbon dioxide, and formic acid

Answer 186

A. Formaldehyde, methanol, and formic acid

Question 187

Which factors contribute to the risk of fires and combustion in absorbent heat production? Select 5

A. Exothermic reactions
B. Desiccated strong base absorbents
C. Hydrated absorbents
D. Buildup of high temperatures
E. Flammable degradation products
F. Avoiding the use of sevoflurane
G. Oxygen or Nitrous rich gasses

Answer 187

A. Exothermic reactions
B. Desiccated strong base absorbents
D. Buildup of high temperatures
E. Flammable degradation products
G) Oxygen or Nitrous

Question 188

What should be done to gas flows after each case according to APSF recommendations?
A. Increased
B. Left unchanged
C. Turned off
D. Reduced to half

Answer 188

C. Turned off
Vaporizers turned off when not in use to prevent dessication

Question 189

How should compact canisters be managed according to APSF recommendations?
A. Change less frequently
B. Change more frequently
C. Change at the same frequency as regular canisters
D. Do not use compact canisters

Answer 189

B. Change more frequently
Also change when color change has happened

Question 190

What is the APSF recommendation for changing absorbent in a two-canister system?
A. Change the top canister only
B. Change both canisters
C. Change the bottom canister only
D. Change one canister at a time

Answer 190

B. Change both canisters