Mechanical Ventilation

Question 1

Define the trigger variable

Answer 1

Parameter that initiates inspiration; how the ventilator determines when to deliver a breath

Question 2

What is the trigger variable in patients not trying to breathe? Trying to breathe?

Answer 2

Time; a change in airway pressure or gas flow as a result from the patients attempt to breathe

Question 3

What is the cycle variable?

Answer 3

Parameter by which ventilation is terminated; typically time; determined by preset RR and I:E ratio. I of 1 commonly recommended

Question 4

What is the limit variable? How does it differ from the time variable?

Answer 4

Parameter that the breath cannot exceed during inspiration; it does not terminate the breath

Question 5

What is the baseline variable?

Answer 5

Controlled during exhalation; airway pressure most common baseline variable manipulated

Question 6

What are the 3 possible breath patterns on a ventilator?

Answer 6

Continuous mandatory ventilation, continuous spontaneous ventilation, intermittent mandatory ventilation

Question 7

In continuous mandatory ventilation the ventilator is responsible for__________________.

Answer 7

All components of the breath.

Question 8

Assist controlled ventilation provides _____________ and is used in patients with ____________ or ____________.

Answer 8

Maximal support of the respiratory system; severe pulmonary disease or no respiratory drive.

Question 9

Define continuous spontaneous ventilation

Answer 9

Ventilation is triggered and cycled by the patient

Question 10

________________ is the breath pattern used in patients with a reliable, adequate respiratory drive

Answer 10

Continuous spontaneous ventilation

Question 11

CPAP is most appropriately used when?

Answer 11

As part of a spontaneous breathing trial to determine a patients suitability for weaning

Question 12

What is PSV?

Answer 12

Pressure support ventilation; the ventilator augments inspiration during spontaneous breaths by increasing airway pressure

Question 13

_________ is designed for use in patients with normal respiratory drive but inadequate ventilator ability

Answer 13

PSV (usually with CPAP)

Question 14

What is SIMV? When is it used?

Answer 14

Synchronized intermittent mandatory ventilation - machine tries to synchronize mandatory breaths with patient inspiratory efforts; unreliable respiratory drive or those that do not require maximal respiratory support

Question 15

What is the basic definition of a ventilator mode?

Answer 15

Identification of a control variable and the breath pattern (ideally including any phase variables)

Question 16

What factors affect the I:E ratio?

Answer 16

inspiratory time, % inspiratory time, inspiratory flow rate in conjunction with respiratory rate

Question 17

Why is an I:E ratio of 1:2 ideal?

Answer 17

To ensure the patient has fully exhaled before the next breath

Question 18

What is breath stacking?

Answer 18

Animal is not able to fully exhale before the next breath, some degree of pressure/air remains in the alveoli at the beginning of the next breath

Question 19

CPAP does what to lung function parameters?

Answer 19

Increases FRC and compliance, enhances gas exchange and oxygenation (does not augment airflow during inspiration more than baseline pressure provides)

Question 20

CPAP alone is only suitable when?

Answer 20

In patients with a strong respiratory drive and adequate ventilatory function

Question 21

PEEP does what to FRC?

Answer 21

Increases it

Question 22

What is intrinsic vs extrinsic PEEP?

Answer 22

Extrinsic set by machine, intrinsic develop as a consequence of inadequate exhalation time or small airway collapse during exhalation

Question 23

What are some positive effects of PEEP?

Answer 23

Recruit collapsed alveoli, prevent collapse of unstable alveoli, improve V/Q, improve pulmonary compliance, reduce work of breathing, reduce VALI

Question 24

How does PEEP reduce VALI?

Answer 24

Preventing injury associated with cyclic re opening and collapse of alveoli with each breath

Question 25

What are some possible detrimental effects of PEEP?

Answer 25

Decrease compliance (if excessive), overdistention of healthy alveoli (have higher compliance already, increase risk of VALI), increased alveolar dead space (obstruction of alveolar capillary flow), increased PVA, decr LV compliance, reduced CO from impaired venous return during expiration

Question 26

Causes of low airway pressure alarm

Answer 26

Leak in the circuit, patient disconnected from circuit

Question 27

Causes of high airway pressure alarm

Answer 27

VC- sudden decrease in pulmonary compliance (endobronch intubation, pneumo), increased system resistance from obstruction in circuit or airways. Patient-ventilator asynchrony

Question 28

What should high and low airway pressure alarms be set at?

Answer 28

Low - 5-10 cm H2O below peek airway pressureHigh - 10 cm above PAP is reasonable

Question 29

What is lung protective ventilation?

Answer 29

Low tidal volume, moderate to high PEEP, +/- permissive hypercapnia

Question 30

List some potential adverse side effects of lung protective ventilation

Answer 30

Increases in ICP, acidemia, PEEP associated cardiovascular compromise

Question 31

List 3 tools to assess PEEP effectiveness

Answer 31

Pressure-volume curve, monitoring changes in gas exchange (increases in PaO2, decreases in PCO2), CT

Question 32

What are recruitment maneuvers?

Answer 32

Used in the ARDS lung - transpulmonary pressure (distending pressure of the lung) increased transiently to recruit collapsed alveoli

Question 33

What are the 4 main determinants of mean airway pressure

Answer 33

Pressure to overcome circuit and airway resistance, pressure to deform lung and expand alveoli, pressure throughout expiratory flow phase, and PEEP

Question 34

In volume control what shape is the flow waveform?

Answer 34

Square or descending ramp

Question 35

In spontaneous breathing the flow waveform will typically be what shape?

Answer 35

Sine

Question 36

In pressure control what shape is the flow waveform typically?

Answer 36

Exponential decay

Question 37

What is a drawback of the constant flow approach?

Answer 37

Modestly higher PIP compared to a decelerating ramp approach to deliver the same tidal volume

Question 38

What information can you gain from the volume scaler?

Answer 38

Rapid qualitative picture of the relative size of spontaneous and mandatory breaths during SIMV or pt effort with CPAP,

Question 39

In mechanically ventilated patients, expiration is usually an _____ (active or passive) process

Answer 39

Passive process. It is driven by the elastic recoil of the respiratory system

Question 40

True or False: There is a significant difference in the duration of weaning, rates of intubation, tracheotomy, or mortality between SIMV and ACV

Answer 40

FALSE

There is no difference

Question 41

True or false: If using ACV as compared with PSV to achieve a set peak airway pressure there is no difference in tidal volume or respiratory rate

Answer 41

FALSE

Tidal volume was significantly higher and machine respiratory rate significantly lower with PSV.

This indicates that peak airway pressure during ACV is not an appropriate variable to adjust PSV for similar levels of assistance.

Question 42

True or false: The work of breathing and the respiratory rate vary inversely with the PSV level

Answer 42

TRUE

Question 43

What are possible causes of a high pressure alarm?

Answer 43

patient coughing, increased airway resistance, decreased compliance, need for airway suctioning, patient biting the ET tube, or bronchospasm

Question 44

What does the ventilator do when a pressure alarm goes off?

Answer 44

it ends inspiration and stops flow to the patient

Question 45

what is the normal setting for a high pressure alarm in regards to PIP?

Answer 45

usually 10 cm H2O above PIP

Question 46

what is the normal setting for the low pressure alarm in regard to PIP?

Answer 46

5-10 cm H2O below PIP

Question 47

what does a low pressure alarm indicate? what are possible causes?

Answer 47

pressure has fallen significantly; usually associated with a leak in patient-ventilator circuit

Question 48

which waveform is useful in deciding if a leak is present?

Answer 48

the volume-time waveform; if it resembles an igloo then the inspired Vt is greater than expired Vt

Question 49

what is the recommendation for placement of connection tubes to prevent false pressure readings or alarms going off?

Answer 49

place the connection tubes above the ET connection to prevent entry of water and secretions; low flow can cause a false pressure reading on the ventilator

Question 50

where do leaks most often occur?

Answer 50

around the humidifier, through humidifier water-feed lines, at water traps, anywhere tubing connections join

others: etCO2 monitor, closed suction catheter, in-line thermometers

Question 51

Differentials for abrupt changes in HR during ventilation?

Answer 51

stress, pain, anxiety, infarction, hypoxia, drug reaction, hypoxemia, hypercapnea, disconnection from ventilator

Question 52

what are 3 areas that measure core body temperature?

Answer 52

esophageal, rectal, pulmonary artery

Question 53

what happens to the CVP measurement during a positive pressure breath?

Answer 53

it increases- in ventilated patients measure at the end of expiration when intrapleural pressure returns to normal or is lowest

Question 54

physical examination of the chest should include what?

Answer 54

inspection, palpation, percussion, auscultation

Question 55

what are differentials for absence of breath sounds?

Answer 55

pneumothorax, complete airway obtruction, complete lung collapse, improper placement of ET tube, pleural effusion

Question 56

what number should intracuff pressures not exceed?

Answer 56

20-25 mm Hg/27-34 cm H2O

Question 57

t/f- tracheal damage and necrosis can occur if the cuff pressure transmitted to the trachea is greater than the perfusion pressure to the trachea?

Answer 57

true

Question 58

t/f- handheld cuff pressure monitors are typically very accurate?

Answer 58

false

Question 59

a high volume/low pressure ET tube cuff should require less than how many ml of air to inflate the cuff?

Answer 59

5 ml

Question 60

5 steps to minimize risk of tracheal necrosis associated with cuff overinflation?

Answer 60

1. use minimal leak technique when possible
2. allow 50-100 ml of Vt to be lost during inspiration
3. Use

Question 61

list 2 reasons why a higher cuff pressure may be required to maintain occlusion

Answer 61

the cuff and ET tube may be too proximal, closer to larynx
may need larger ET tube
patient’s trachea may be dilated from cuff damage

Question 62

what is the most common cause of a low or nonexistent cuff pressure?

Answer 62

leak in ET cuff or pilot system

Question 63

how often should the ET tube be repositioned in the mouth?

Answer 63

8-12 hrs

Question 64

list causes of decreased Cs (static compliance)

Answer 64

air trapping, pulmonary edema, ,atelectasis, consolidation, pneumonia, pneumothorax, hemothorax, pleural effusion

Question 65

during pressure controlled ventilation, increased tidal volume delivery with the same pressure indicates what?

Answer 65

improved compliance or decreased airway resistance

Question 66

total resistance is the sum of what?

Answer 66

airway and tissue resistance

Question 67

what can cause increased tissue resistance?

Answer 67

ascites, pleural effusion

Question 68

what is the shape of the P-V curve for a patient with ARDS?

Answer 68

sigmoid

Question 69

True or false, when the ventilator is patient triggered, the pressure or flow required to trigger the ventilator should be no more than -1 or -2 cm H20

Answer 69

TRUE

No more than this should be required to trigger the ventilator

Question 70

If a ventilator is flow triggered, what sensitivity should it be set at?

Answer 70

Sensitivity should be around a flow change of 2 to 3 L/min

Question 71

What changes can you make to reduce auto-PEEP?

Answer 71

Increasing the flow (reducing inspiratory time)
Reducing tidal volume
Reducing the rate (reducing Ve)
Suctioning the patient
Changing the mode to allow for more spontaneous breaths

Question 72

What is compressible volume?

Answer 72

Volume loss within the patient circuit to the effects of tubing compliance

Question 73

How do you calculate compressible volume?

Answer 73

PIP x Ct

Ct = tubing compliance

Question 74

What two factors must be considered when determining alveolar ventilation?

Answer 74

Anatomic dead space

Mechanical dead space

Question 75

A consistent Vt with an increasing Ppeak is suggestive of what possible things?

Answer 75

Either reduction in lung compliance (Cl) or increase in airway resistance (Raw)

Question 76

What value should the Pplateau be kept below?

Answer 76

Below 30 cm H20 to avoid ventilator induced lung injury

Question 77

What is the equation for transairway pressure (Pta)?

Answer 77

Pta = PIP - Pplateau

Question 78

What is end expiratory pressure (EEP)?

Answer 78

The lowest pressure measured during the expiratory phase of a breath

Question 79

Below what oxygen saturation are pulse oximeters inaccurate?

Answer 79

Below 80%

Question 80

Name 4 things that can interfere with the reading on a pulse oximeter

Answer 80

Low perfusion
Abnormal hemoglobin (methemoglobin or carboxyhemoglobin)
Skin pigmentation
Ambient light interference
Motion
Low oxygen saturation (

Question 81

What is fractional hemoglobin saturation?

Answer 81

The amount of oxyhemoglobin divided by the sum of the concentrations of all four types of hemoglobin

Fractional O2Hb = O2Hb / [HHb + O2Hb + COHb = MetHb]

Question 82

What is functional hemoglobin saturation?

Answer 82

The amount of oxyhemoglobin divided by the concentration of hemoglobin capable of carrying oxygen

Function O2Hb = O2Hb / [HHb = O2Hb]

Question 83

Do pulse oximeters measure functional or fractional hemoglobin saturation?

Answer 83

They measure functional. They are only capable of using two wavelengths to quantify the amount of HHb and O2HB. CO-oximeters can measure all four types of hemoglobin so can measure fractional hemoglobin saturation.

Question 84

True or False: The presence of COHb will lead to an underestimation of SpO2

Answer 84

FALSE

It will lead to an OVERestimation of SpO2

Question 85

How does methemoglobinemia affect the SpO2 value?

Answer 85

MetHb can absorb both red and infrared light. If enough is present to absorb all pulsatile absorption, the pulse oximeter will measure a red-to-infrared ratio of 1:1, corresponding to an SpO2 of 85%

Question 86

What effect does skin pigmentation have on SpO2?

Answer 86

Darker skin pigmentation will read a higher SpO2

Question 87

True or False: Hyperbilirubinemia affects the SpO2 measurement

Answer 87

FALSE: it does not appear to affect the pulse oximeter reading

Question 88

On the oxyhemoglobin dissociation curve, what things cause increased affinity of hemoglobin for oxygen and what effect does this have on the curve?

Answer 88

Acute alkalosis
Decreased PCO2
Decreased temperature
Low levels of 2, 3 DPG
Carboxyhemoglobin
Methemoglobin
Abnormal hemoglobin

Shifts the curve to the LEFT

Question 89

On the oxyhemoglobin dissociation curve, what things cause decreased affinity of hemoglobin for oxygen and what effect does this have on the curve?

Answer 89

Acute acidosis
High CO2
Increased temperature
High levels of 2, 3 DPG
Abnormal hemoglobin

Shifts the curve to the RIGHT

Question 90

How is etCO2 measured with an infrared capnometer?

Answer 90

The concentration of CO2 is estimated as its concentration is directly related to the amount of infrared light absorbed.

Question 91

What is pressure broadening and what effect does it have on the CO2 reading?

Answer 91

The presence of other gases such as O2 and N2O because the peak absorbance of infrared light by CO2 lies between the peak absorbance for O2 and N20.

Pressure broadening results in falsely high CO2 reading

Question 92

How do we minimize the effect of pressure broadening?

Answer 92

Removing water vapor from the case sample before it is analyzed, and by using electronic filters to subtract the infrared absorption by gases other than CO2

Question 93

What factors influence the etCO2?

Answer 93

Alveolar PCO2
VCO2 (CO2 production which is dependent on metabolic rate)
Effectiveness of ventilation

Question 94

What is the single-breath CO2 curve?

Answer 94

It is produced by the integration of airway flow and CO2 concentration and is presented on a breath to breath bases.

Question 95

On a single-breath CO2 curve, what do the following areas represent: Area X, Area Y, Area Z

Answer 95

Area X: Actual amount of CO2 exhaled
Area Y: Amount of CO2 that is not eliminated because of alveolar dead space
Area Z: Amount of CO2 that is not eliminated because of anatomic dead space

Question 96

What four factors influence the amount of CO2 exhaled?

Answer 96

CO2 production
Perfusion of the lungs
Diffusion
Ventilation

Question 97

On the capnogram, what are the four phases?

Where on the curve is etCO2 measured?

Answer 97

Phase I: Initial gas is exhaled from the conducting airways

Phase 2: Alveolar gas containing CO2 mixes with gas from the anatomic airways and the CO2 concentration rises

Phase 3: The curve plateaus as alveolar gas is exhaled

Phase 4: Inspiration, concentration of CO2 falls to zero

etCO2 is measured at the end of the alveolar phase or phase 3

Question 98

what conditions can lead to reduction of exhaled nitric oxide?

Answer 98

systemic hypertension, pulmonary hypertension, cystic fibrosis, sickle cell anemia, ciliary dyskinesis

Question 99

what conditions lead to increased levels of exhaled nitric oxide?

Answer 99

asthma, bronchiectasis, airway viral infections, alveolitis, allergic rhinitis, pulmonary sarcoidosis, chronic bronchitis, pneumonia

Question 100

what effect does NO have on the airways?

Answer 100

potent dilatory effects on pulmonary vessels and airways; facilitates coordinated beating of ciliated epithelial cells

Question 101

how do transcutaneous monitoring systems work (i.e. how are they different from SpO2 and capnography, which use spectrophotometric analysis)

Answer 101

uses modified blood gas electrodes to measure the O2 and CO2 tensions at the skin surface

Question 102

List examples of hypo and hypermetabolic states

Answer 102

Hypo: starvation, hypoT4, anesthesia, sedation, coma, hypothermia

Hyper: pancreatitis, hyperT4, drugs, pregnancy, hyperthermia, seizures, burns

Question 103

what are the most common airway pressure measurements that most ventilators display?

Answer 103

peak inspiratory pressure, static/plateau pressure

Question 104

List differentials for sudden increases in peak inspiratory pressure

Answer 104

bronchospasm, mucus plugging, partially blocked heat/moisture exchanger, incorrect ET size, water in ventilator tubing, malfunctioning expiratory valves, barotrauma, VILI

Question 105

What is the name of the law that states that a twofold decrease in airway diameter will result in a 16x increase in airway resistance?

Answer 105

Poiseuille’s law

Question 106

Describe and give examples of intrinsic vs extrinsic work of breathing

Answer 106

Intrinsic: work done to overcome normal elastic and resistive forces; work to overcome disorder or disease affecting lung/thorax (ex: fibrosis of lungs)

Extrinsic: work imposed by systems that are added to the patient (ex: ET tube, machine sensitivity, humidification device)

Question 107

In a static pressure volume loop what does the upper inflection point on the inspiratory limb represent

Answer 107

the point at which no more alveoli are being recruited

Question 108

in a static pressure volume loop what does the line from the lower to upper inflection point mean on the inspiratory limb?

Answer 108

it represents the respiratory system compliance

Question 109

what is the current recommendation for using static pressure volume loops to set PEEP?

Answer 109

set peep 2-3 cm H2O above the upper inflection point detected during deflation of the lungs

Question 110

What are 3 common indications for applying recruitement maneuvers?

Answer 110

ALI/ARDS, post-op atelectasis, after suctioning maneuvers, after circuit disconnect

Question 111

How can you ensure the lungs are protected from overdistension when applying recruitment maneuvers?

Answer 111

keep PIP (peak inspiratory pressure) lower than the upper inflection point of the PV loop

Question 112

At what pressure does lung derecruitment begin? At what pressure does the lung completely collapse?

Answer 112

derecruitment- 8 cm h2o; collapse- 4 cm h2o

Question 113

the ARDSnet study suggested what level of PEEP very early in the management of ARDS in people?

Answer 113

15 cm h2o

Question 114

the sigmoid shape of a pressure volume loop suggests what?

Answer 114

that different areas of the lung open at different pressures

Question 115

What are some adverse effects associated with increased thoracic pressure for extended periods of time (>40 sec)?

Answer 115

decreased venous return, drop in cardiac output, drop in blood pressure; uneven pressure to the lungs causing shifting of blood to other areas of the lungs

Question 116

what types of things affect chest wall compliance?

Answer 116

forces from overlying ribs and muscles, force from the diaphragm, pressures from abdominal contents, obesity

Question 117

T/F- higher than normal pressures may be necessary in critically ill and/or obese patients in order to recruit collapsed alveoli?

Answer 117

True- they have decreased chest wall compliance and often increased intra-abdominal pressures

Question 118

List potential complications associated with lung recruitment maneuvers

Answer 118

Barotrauma, pneumothorax, subcutaneous emphysema, pneumomediastinum, hypotension

Question 119

Name some types of recruitment maneuvers

Answer 119

Sustained inflation, PC-CMV with high PEEP levels, PC CMV with increased PEEP, recruitment and decremental PEEP, sigh techniques

Question 120

T/F- recruitment maneuvers are more effective in patients with primary ARDS than secondary ARDS?

Answer 120

False- more effective with secondary ARDS

Question 121

Name and describe the two categories of ARDS according to Pilbeam

Answer 121

• Indirect: secondary/nonpulmonary, associated with acute systemic inflammation such as acute sepsis or pancreatitis
• Direct: primary/pulmonary, pneumonia, aspiration, near-drownings

Question 122

List possible chemicals that mediate the inflammatory response in ARDS

Answer 122

reactive oxygen species, nitric oxide, leukotrienes, cytokines, proteases, platelet activating factor, cationic proteins, interleukins (1, 6, 8, 10), TNFalpha

Question 123

Describe the general shape of a pressure-time scalar for pressure controlled ventilation vs volume controlled ventilation

Answer 123

Pressure controlled is a flat top

Volume controlled is a “shark fin” shape

Question 124

What flow pattern is seen on the flow-time scalar for a volume controlled breath?

Answer 124

Square shaped

Question 125

What does air-trapping or auto-peep look like on a flow-time scalar?

Answer 125

Expiratory flow does not return to baseline before the next breath begins

Question 126

Describe the flow-time scalar for a pressure supported breath?

Answer 126

Decelerating flow pattern, flat-topped airway pressure wave

Question 127

Describe the flow-time scalar for a synchronized breath?

Answer 127

Triangular shaped pressure wave

Question 128

How can you tell the difference between a patient triggered controlled or supported breath on a flow-time scalar?

Answer 128

With supported breaths the patient determines the inspiratory time so it will be variable

With controlled breaths, the inspiratory time will be identical

Question 129

How can you tell that asynchrony is present when evaluating the flow-time scalar?

Answer 129

If the number of triggering episodes is greater than the number of breaths then asynchrony is present

Question 130

What does the slope of a pressure-volume loop represent?

Answer 130

Dynamic compliance

It should be around 45 degrees

Question 131

How is compliance defined?

Answer 131

Change in volume in relation to the change in intra-pleural pressure

Question 132

Name common causes of increase pulmonary resistance

Answer 132

Bronchospasm
Airway secretions
Small-diameter ET tube
Mucosal edema of airways

Question 133

Name common causes of decreased pulmonary compliance

Answer 133

Pleural space disease
Pulmonary parenchymal disease
Single-lung intubation
Abdominal distension
Chest wall disease or deformity

Question 134

What do the inflection points represent on a static P-V loop?

Answer 134

A sudden change in alveolar recruitment during inspiration and derecruitment during expiration

Question 135

What does an increase in the width of a P-V loop represent?

Answer 135

Increased resistance

Question 136

What is hysteresis?

Answer 136

Lag in the change in volume compared with the rate of change in pressure that results from resistance to deformation (elasticity) and resistance of the airways

Question 137

How can the work of breathing by the patient during mechanical ventilation be indirectly measured?

Answer 137

By plotting esophageal pressures - esophageal pressures are a surrogate for measuring intrapleural pressure and intrapleural pressure changes due to patient work