FINAL!!!

Question 1

What happens in volume control (3)

Answer 1

• Volume and flow remain constant
• Pressure varies based on lung mechanics
• Guaranteed VE

Question 2

Madatory Settings for volume control (5)

Answer 2

• FIO2
• Vt
• PEEP
• Flow
• RR

Question 3

What happens in pressure control (3)

Answer 3

• Pressure remains constant
• Volume and flow varies based on lung mechanics
• Lung protection stratagey

Question 4

Mandatory Settings for pressure control (5)

Answer 4

• FIO2
• Inspiratory time (I- time)
• PEEP
• RR
• Inspiratory pressure

Question 5

In pressure we set the

Answer 5

I-time and the pt can take whatever flow based on how they breathe

Question 6

How can we use inspiratory pressure to manipulate Vt?

Answer 6

increase the PIP to get a higher Vt

Question 7

Example: I want my pt to get 500 vt. My PIP is set to 20 cm H20, but the pt is only getting 400. I would increase the PIP, that way the pt can get the 500 vt

Answer 7

something to know

Question 8

Increased Raw is

Answer 8

BAD

Question 9

What happens with PIP and VT when raw is increased?

Answer 9

• PIP goes UP
• Vt goes DOWN

Question 10

What can increase Raw? (6)

Answer 10

• secretions
• water in tubing
• bronchospasm
• COPD
• kink in tubing
• mucus plugging

Question 11

Decreased Raw is

Answer 11

GOOD

Question 12

If I’m in volume control, and I have decreased Raw, what should happen to the Vt and PIP?

Answer 12

• Vt goes UP (but its constant b/c you’re in volume control)
• PIP goes DOWN

Question 13

If pt has bronchospasms Raw will increase, once you give them a bronchodilator Raw will decrease

Answer 13

something to know

Question 14

If a pt is in pressure control and the pt has decreased Raw, what will happen to Vt and PIP?

Answer 14

• Vt goes UP
• PIP goes DOWN ( but it’s constant b/c you’re in pressure control)

Question 15

Increased compliance is _______

Answer 15

GOOD

Question 16

When a pt has increased compliance what happens with VT and PIP?

Answer 16

• Vt goes UP
• PIP goes DOWN

Question 17

What is a disease process that has increased compliance?

Answer 17

Emphysema

Question 18

Decreased compliance is ______

Answer 18

BAD

Question 19

When a pt has decreased compliance what happens to Vt and PIP?

Answer 19

• Vt goes DOWN
• PIP goes UP

Question 20

What is a disease process that has decreased compliance

Answer 20

ARDS

Question 21

Triggers=

Answer 21

starts the breath

Question 22

What are some triggers? (5)

Answer 22

• time
• pressure (most common)
• flow (most common)
• volume
• Patient

Question 23

Limit=

Answer 23

the maximum value that can be attained during the breath

Question 24

LIMITS DO NOT END THE BREATH

Answer 24

something to know

Question 25

Cycle=

Answer 25

ends the breath

Question 26

Examples of cycle (4)

Answer 26

• time
• flow
• pressure
• volume

Question 27

Baseline determines

Answer 27

what happens during exhalation

Question 28

Baseline can either be

Answer 28

zero or PEEP

Question 29

If a pt does not return back to baseline, what is occurring?

Answer 29

Air-trapping (auto-peep)

Question 30

What type of pt is most likely to air trap?

Answer 30

COPD

Question 31

What is Assist control?

Answer 31

Pt has mandatory breaths. The pt can trigger extra breaths but they don’t have to b/c it provides everything they need. Cannot have pressure support in this mode

Question 32

Full support is when the vent

Answer 32

is doing majority of the WOB

Question 33

Partial support

Answer 33

the vent does some of the WOB

Question 34

SIMV

Answer 34

Synchronized breaths. The pt is expected to do some of the WOB on their own. Can have spontaneous breaths in between mandatory breaths

Question 35

Spontaneous modes

Answer 35

CPAP/ pressure support

Question 36

APRV

Answer 36

• 2 different pressure levels of CPAP
• Both pressure levels are time triggered and time-cycled
• P high and P low indicate the levels of pressure and T high and T low are the time spent in high and low airway pressures
• The pt spends longer time at the higher-pressure level, followed by a short release to release CO2

Question 37

APRV intially was used for

Answer 37

improving oxygenation

Question 38

Mean Airway Pressure (Paw) affects oxygenation b/c

Answer 38

it is when the alveoli are expanded, but not overdistended, which allows more surface area and time for gas exchange (that is how increasing Paw improves oxygenation)

Question 39

PRVC

Answer 39

• Controlling the Vt, and regulating the amount of pressure that is given to achieve the Vt
• If the volume delivered is less than the set Vt, the vent increases pressure delivery progressively, over several breaths until the set and targeted Vt are about equal

Question 40

Example: If the pressure limit is 25 cm H20 and the vent requires more than 20 cm H20 to deliver a Vt of 500 mL, an alarm activates, and the pressure delivery is limited to 20 cm H20

Answer 40

!

Question 41

What does the flow setting on MV determine?

Answer 41

how fast the inspired gas or Vt will be delivered to the pt

Question 42

Example: In volume control, if I set the Vt to 500 mL, inspiratory flow is how fast can the vent delivers the 500 mL to the pt

Answer 42

!

Question 43

Once the flow is set, it then determines the

Answer 43

I-time

Question 44

The faster the flow

Answer 44

the shorter the Ti

Question 45

What is a disadvantage of a shorter Ti?

Answer 45

higher peak pressure

Question 46

What is an advantage of shorter Ti?

Answer 46

a longer Te

Question 47

Slower flows may reduce (3)

Answer 47

peak pressures, improve gas distribution, and increase Paw

Question 48

An advantage of a longer Ti is that it can

Answer 48

improve ventilation

Question 49

A disadvantage of a longer Ti is it can cause

Answer 49

cardiac side effects; also it if you have a longer Ti the pt is spending less time in expiration, which can cause air-trapping

Question 50

For I-time, The goal is to have the

Answer 50

shortest Ti possible

Question 51

An initial setting flow is normally set to

Answer 51

1 second (0.8- 1.2 seconds)

Question 52

Intial peak flow is

Answer 52

60 (40-80 L/m)

Question 53

What are the most common flow patterns?

Answer 53

• constant (rectangular or square)
• descending (decelerating)

Question 54

A constant flow pattern provides the

Answer 54

shortest Ti

Question 55

Descending ramp is most like (2)

Answer 55

natural breathing
- Flow is the greatest at the beginning of the breath

Question 56

What are the waveforms possible for pressure (2)

Answer 56

• rectangle
• exponential (rise)

Question 57

What are the waveforms possible for volume? (2)

Answer 57

• ascending ramp
• sinusodal

Question 58

What are the waveforms possible for flow? (5)

Answer 58

• rectangular
• sinusodal
• ascending
• descending
• exponential (decay)

Question 59

What are the 4 types of hypoxemia

Answer 59

• Hypoxemic
• Anemic
• Circulatory
• Histotoxic

Question 60

Hypoxemic hypoxia (3)

Answer 60

• lower than normal PaO2
• ascent to altitude
• hypoventilation

Question 61

Anemic hypoxia (3)

Answer 61

• lower than normal RBC count (anemia)
• abnormal hemoglobin
• carbon monoxide poising

Question 62

Circulatory hypoxia (2)

Answer 62

• reduced cardiac output
• decreased tissue perfusion

Question 63

Histotoxic hypoxia

Answer 63

cyanide poisoning

Question 64

List 2 disadvantage of pressure control

Answer 64

• volume and flow varies based on lung characteristics
• Vt and Ve decreases when lung characteristics deteriorate

Question 65

List 2 disadvantage of volume control

Answer 65

• when lung conditions worsen it can cause peak pressure to rise leading to overdistention
• If the sensitivity level is not set appropriately for the pt, it can make it more difficult for a pt to trigger inspiration

Question 66

How should you instruct a pt to perform IPPB?

Answer 66

Slow and deep breaths

Question 67

What are indications for IPPB? (2)

Answer 67

• pts with pulmonary atelectasis
• inability to clear secretions

Question 68

What are contraindications of IPPB?

Answer 68

• Tension pneumothorax
• ICP > 15 mm Hg
• Hemodynamic instability
• Active hemoptysis
• Tracheoesophageal fistula
• Recent esophageal surgery
• Radiographic evidence of blebs
• Recent facial, oral, or skull surgery
• singultus (hiccups)
• Nausea

Question 69

What are some Hazards of IPPB (5)

Answer 69

• Hyperventilation and respiratory alkalosis
• discomfort secondary to inadequate pain control
• pulmonary barotrauma
• exacerbation of bronchospasm
• fatigue

Question 70

MIP (NIF or Pimax) normal and critical

Answer 70

Normal: -100 to -50 cm H20
Critical: -20 - 0 cm H20

Question 71

VC normal and critical

Answer 71

Normal: 65 - 75 mL/kg
Critical: <40

Question 72

Vt normal and critical

Answer 72

Normal: 5- 8 mL/kg
Critical: <5

Question 73

Define Automatcity

Answer 73

The ability of the cardiac muscles to initiate a spontaneous electrical impulse (depolarization and repolarization)

Question 74

Define Contraction

Question 75

Define Autopolarization

Question 76

Define Polarization

Answer 76

No electrical activity takes place

Question 77

minute ventilation equation

Answer 77

VE= Vt x RR

Question 78

Alveolar minute ventilation

Answer 78

VA= (VT-VD) x RR

Question 79

Ideal Body Weight

Answer 79

M: 106+6 (H-60)/2
W: 105 +5 (H-60)/2

Question 80

Alveolar air equation

Answer 80

PAO2=(PB-PH20) x FiO2 - (PaCO2 x 1.25)

Question 81

A-a gradient

Answer 81

P(A-a)O2

Question 82

CaO2

Answer 82

(SaO2 x HB) x 1.34

Question 83

CVO2

Answer 83

(SvO2 x HB) x 1.34

Question 84

What are the intial settings for BiPAP

Answer 84

IPAP: 8 to 10 cm H20
EPAP: 4 to 5 cm H20

Question 85

What is the goal of NIV

Answer 85

To improve gas exchange by resting the respiratory muscles and increasing alveolar ventilation

Question 86

Goals for LTMV

Answer 86

To improve the pt’s quality of life by:
1. Enhancing the individual’s living potential
2. Improving physical and physiological levels of function
3. Reducing morbidity
4. Lessening hospitalizations
5. Extending life
6. Providing cost-effective care