Exam 1- Capnography (6/13/23)

Question 1

Effects of Hypercarbia

Answer 1

• Respiratory acidosis can develop over time
• Increases cerebral blood flow (CBF)
• Increases ICP in susceptible patients
• Increases pulmonary vascular resistance, vasoconstriction
• Potassium shifts from intracellular to intravascular

Question 2

Effects of Hypocarbia

Answer 2

• Respiratory alkalosis
• Decreases CBF
• Decreases pulmonary vascular resistance, vasodilation
• Potassium shifts to the intracellular space
• Blunts normal urge to breathe

Question 3

Capnography provides information primarily on ventilation but can give info on:

Answer 3

• Pulmonary blood flow
• Aerobic metabolism
• Placement of ETT/LMA (presence of ETCO2)
• Integrity of breathing circuit
• Estimates the adequacy of cardiac output

Question 4

What is the Bohr equation used to calculate?

Answer 4

• Physiological dead space

Question 5

Define dead space.

Answer 5

• Volume of each breath inhaled that does not participate in gas exchange

Question 6

Differentiate anatomical and physiological dead space.

Answer 6

• Anatomic – conducting zones of the airway (nose, trachea, bronchi)
• Physiologic – airway dead space + alveolar dead space

Question 7

Define alveolar dead space

Answer 7

• Portion of the physiologic dead space that does not take part in gas exchange but is within the alveolar space

Question 8

Conditions that increase alveolar dead space (V/Q mismatching)

Answer 8

• Hypovolemia
• Pulmonary hypotension
• Pulmonary embolus
• Ventilation of nonvascular airspace
• Obstruction of precapillary pulmonary vessels
• Obstruction of the pulmonary circulation by external forces
• Overdistension of the alveoli

Question 9

Measurement and quantification of inhaled or exhaled CO2 concentrations.

Answer 9

• Capnometry

Question 10

What is capnography?

Answer 10

• Method of CO2 measurement and a graphic display of time
• Detection of CO2 breath-by-breath
• Best method to confirm endotracheal intubation

Question 11

What is time capnography?

Answer 11

• Pressure vs time plot; most common representation
• CO2 concentrations digitally reported as ‘inspired’ and ‘end tidal’

Question 12

High-speed vs. low-speed time capnography.

Answer 12

• High-speed – user can interpret information about each breath
• Slow-speed – appreciation of the expired and inspired trend

Question 13

What is the most common gas sampling system?

Answer 13

• Side-stream gas analyzer (time delay)

Question 14

What phase on a capnograph will an ETCO2 be measured at?

Answer 14

• ETCO2 measured at the end-point of phase 3.

Question 15

What can increase ETCO2?

Answer 15

Question 16

What can decrease ETCO2?

Answer 16

Question 17

Difference between PaCO2 and ETCO2 is approx ____ mmHg.

Answer 17

• 5 mmHg

Ex: ETCO2 of 35 mm Hg = PaCO2 of approx. 40 mm Hg

Question 18

Problems that increase the difference between PaCO2 and ETCO2.

Answer 18

• V/Q mismatching increases the difference between PaCO2 and PACO2 (PE, endobronchial intubation)
• Breathing patterns that fail to deliver alveolar gas at the sampling site, increases the difference between PACO2 and true ETCO2 (alveolar gas) - COPD
• Problems with the capnograph increase the difference between true ETCO2 (alveolar gas) and measured ETCO2 (capnograph)

Question 19

CO2 measurement most commonly relies on _____ light absorption techniques.

Answer 19

• Infrared (IR)

The greater the CO2 in the sample, the less IR light that reaches the detector

Question 20

Describe the color change with a CO2 chemical indicator.

Answer 20

• Purple – No CO2
• Yellow – CO2

Sensitive to low levels of CO2
ETT placement still needs verification by alternative means

Question 21

What are the CO2 monitor requirements/ standards?

Answer 21

• CO2 reading within +/- 12% of actual value
• Manufacturers must disclose interference caused by ethanol, acetone, halogenated volatiles
• Must have a high CO2 alarm for inhaled and exhaled CO2
• Must have an alarm for low-exhaled CO2

Question 22

Information that can be interpreted from a time capnograph?

Answer 22

• Interpreting CO2 values
• Approximate blood CO2 levels
• Pulmonary blood flow
• Alveolar ventilation
• Differential diagnosis of loss of exhaled CO2 (esophageal intubation, cardiac arrest)

Question 23

What are the inspiratory and expiratory segments of a normal capnograph?

Answer 23

• Inspiratory – Phase 0
• Expiratory – Phases I, II, and III

Question 24

Describe Phase I of a normal capnograph.

Answer 24

• Baseline
• Exhalation of anatomic dead space and the apparatus (ETT, LMA)
• Essentially no CO2
• 1/3 of tidal volume is exhaled

Question 25

Describe Phase II of a normal capnograph.

Answer 25

• Expiratory upstroke begins (CO2-rich alveolar gas)
• Sampling of alveolar gases
• Normally steep uprise

Question 26

Describe Phase III of a normal capnograph.

Answer 26

• Alveolar Plateau phase
• Normally representative of CO2 in alveolus
• Can be representative of ventilation heterogeneity, slightly increasing slope

Question 27

Describe Phase 0 of a normal capnograph.

Answer 27

• Sometimes called phase IV
• Inspiration of fresh gas, remaining CO2 washed out
• Downstroke returns to baseline

Question 28

Describe the Occasional Phase IV (Phase IV Prime) of a capnograph.

Answer 28

• A sharp upstroke in PCO2 at the very end of phase III
• Upstroke probably results from the closure of lung units with lower PCO2
• Allows for regions with higher CO2 to contribute to more of the exhaled gas sample
• Seen in pregnant and obese pts
• Decreased FRC and lung capacity

Question 29

Describe the alpha angle of the capnograph.

Answer 29

• Separates phase II and phase III
• 100 – 110 degrees
• Angle increases with an expiratory airflow obstruction
• Ex: COPD, bronchospasm, or kinked ETT

Question 30

Describe the beta angle of the capnograph.

Answer 30

• Separates phase III and phase 0
• 90 degrees
• Angle increases with malfunctioning inspiratory unidirectional valves, rebreathing, and low tidal volume with rapid respiratory rate

Question 31

Describe the capnograph

Answer 31

• Normal Capnograph
• Mechanical Ventilation

Question 32

Describe the capnograph

Answer 32

• Normal Capnograph
• Spontaneous Ventilation

Question 33

What is the issue with this capnograph?

Answer 33

• Inadequate Seal around ETT

Question 34

What is causing this capnograph?

Answer 34

• Faulty Inspiratory Valve (top capnograph)
• Rebreathing (bottom capnograph)

Question 35

What is causing this capnograph?

Answer 35

• Sample line leak
  Take note that this a small wave form and that ETCO2 does not even reach 40 mmHg

Question 36

What is causing this capnograph?

Answer 36

• Hyperventilation
• Gradually decreasing waveforms

Question 37

What is causing this capnograph?

Answer 37

• Hypoventilation
• Gradually increasing waveforms

Question 38

What is causing this capnograph?

Answer 38

• Airway obstruction

Question 39

What is causing this capnograph?

Answer 39

• Cardiac oscillation
• Often seen in pediatric patients, the heart is close to the trachea

Question 40

What is causing this capnograph?

Answer 40

• Re-breathing soda lime exhaustion
  Take note that rebreathing is occurring. The capnograph does not return to baseline.

Question 41

What is causing this capnograph?

Answer 41

• NMBD’s wearing off
• Presence of a “curare cleft”

Question 42

What is causing this capnograph?

Answer 42

• Over-breathing
• Notice the spontaneous breath between the mechanical breath

Question 43

What is causing this capnograph?

Answer 43

• Esophageal intubation