Lecture 14: Pulmonary Function Tests (Exam III)

Question 1

Where on the PFT graph below does N₂ start to show up on our nitrogen meter?

Answer 1

Question 2

What is the partial pressure of nitrogen in room air?

Answer 2

560mmHg

Question 3

What test is depicted in the graph below?

Answer 3

Nitrogen washout test

Question 4

What should a normal nitrogen concentration in the atmosphere be?

Answer 4

75 - 80 %

Question 5

What percentage nitrogen should a healthy 20 y/o have at 3 minutes into a nitrogen washout test?

Answer 5

2.5% in 3 min

Question 6

What is a normal reading on a nitrogen washout test?

Answer 6

2.5% in less than 7 min

Question 7

What is an abnormal reading on a nitrogen washout test?

Answer 7

2.5% in greater than 7 min

Question 8

Which of the two nitrogen washout tests below displays an abnormal and uneven air distribution?

Answer 8

Right graph

Question 9

How might V_D be estimated from the graph below?

Answer 9

V_D = phase I + ½(phase II)

Question 10

What lung volume comprises the entirety of phase I in the figure below?

Answer 10

V_D (Anatomical Dead Space)

Question 11

What lung volume(s) comprise phase II in the figure below?

Answer 11

Phase II = Transitional Phase = V_D + V_A air

Question 12

Where is air coming from in phase III in the figure below?
What is the nitrogen concentration of this air?

Answer 12

• All areas of the lungs
• [N₂] ≈ 20%

Question 13

What phase in a closing capacity/volume test is the longest for healthy people?

Answer 13

Phase III

Question 14

What causes the sharp upswing noted in Phase IV in the figure below?

Answer 14

Lung base small airways start to collapse so [N₂] starts to increase.

Question 15

In what area of the graph below will we notice excessive compliance?

Answer 15

Question 16

At what lung volume does inspiration start when conducting a closing volume/capacity test?

Answer 16

RV

Question 17

What is indicated by 1 in the figure below?

Answer 17

Closing Volume

Question 18

What is indicated by 2 in the figure below?

Answer 18

Residual Volume

Question 19

What is indicated by 3 in the figure below?

Answer 19

Closing Capacity

Question 20

What is indicated by 4 in the figure below?

Answer 20

Vital Capacity

Question 21

What lung capacity changes the most with age?

Answer 21

Closing Capacity

Question 22

At what age will closing capacity equate to functional residual capacity?
What does this mean?

Answer 22

• Age: 50
• CC = FRC means that the airways of the lung base collapse in normal respiration.

Question 23

Which lung capacities decrease with age?

Answer 23

• IC
• VC
• ERV

Question 24

Which lung capacities increase with age?

Answer 24

• FRC
• RV
• CC

Question 25

Where would closing volume be located on the graph below?

Answer 25

Question 26

Why are small airways more prone to collapse as we age?

Answer 26

Loss of traction

Question 27

If a full inspiration of FiO₂ 100% were taken from this lung in the graph below, where would [N₂] be more diluted?

Answer 27

Base of the lung due to having a lower starting volume of 20%. *someone check this one, the O₂ should theoretically go to the apex first since we're taking an inspiration from RV, right?*

Question 28

At what stage of the respiratory cycle would you expect a healthy person to have the best possible traction?

Answer 28

2 seconds into inspiration and right before expiration when the lungs are fullest. *Best traction at higher lung volumes.*

Question 29

Does traction increase or decrease as we get closer to RV?

Answer 29

Traction decreases

Question 30

How can vital capacity be determined from the graph below?

Answer 30

TLC - RV

Question 31

Would effort-dependent expiration occur at higher or lower lung volumes?

Answer 31

Effort-dependent expiration = TLC and higher lung volumes

Question 32

Would effort-independent expiration occur at higher or lower lung volumes?

Answer 32

Effort-independent expiration = RV and lower lung volumes

Question 33

In a healthy patient, what percentage of vital capacity expiration should occur in the first second of expiration?

Answer 33

80% of VC expired in 1st second of expiration.

Question 34

What is the forced expiratory flow rate in someone young and healthy?

Answer 34

10 L/s

Question 35

What sort of pathology would you expect from the peak expiratory curve below? Why?

Answer 35

- Emphysema - Loss of P_ER causes leftward shift of effort independent expiratory flow.

Question 36

What sort of pathology is indicated by figure 1 below?

Answer 36

Obstructive disease (Emphysema)

Question 37

What sort of pathology is indicated by figure 2 below?

Answer 37

No Pathology, normal expiratory function curve.

Question 38

What sort of pathology is indicated by figure 3 below?

Answer 38

Restrictive disease (Fibrosis)

Question 39

What causes the pathology noted by 1 in the figure below?

Answer 39

Emphysema → Loss of P_ER

Question 40

Which of the following curves would have the greatest degree of effort-independent expiratory flow?

Answer 40

1. Emphysema

Question 41

What are the peak expiratory flow rates of each of the curves below?

Answer 41

1. 8 L/s 2. 13 L/s 3. 10 L/s

Question 42

What are vital capacities of each of the curves below?

Answer 42

1. **VC ≈ 3.75L** (8.5 - 4.75) 2. **VC ≈ 4.5L** (6 - 1) 3. **VC ≈ 3L** (4.1 - 1.1)

Question 43

Does a forced expiration or a passive expiration present more of a risk for small airway collapse?

Answer 43

Forced Expiration

Question 44

When would small airway collapse be more likely?

Answer 44

COPD/Emphysema

Question 45

Loss of what capability would increase the risk of small airway collapse?

Answer 45

P_ER

Question 46

How does pursed-lip breathing prevent airway collapse?

Answer 46

Pursed-lip breathing will restrict outflow and increase airway pressures **Airway pressures > P_IP = no collapse**

Question 47

What causes the increased pressures seen in the rightmost figure below?

Answer 47

Contraction of intercostal muscles, accessory muscles, and abdominal muscles.

Question 48

Loss of _____ will result in more collapsible airways.

Answer 48

P_ER (Traction)

Question 49

The flow-volume curve below is indicative of what?

Answer 49

Fixed Obstruction (ex. ETT)

Question 50

The flow-volume curve below is indicative of what?

Answer 50

Variable extra-thoracic obstruction (ex. scar tissue, paralyzed vocal cords)

Question 51

The flow-volume curve below is indicative of what?

Answer 51

Variable intra-thoracic obstruction (ex. small airway collapse, traction loss on expiration)

Question 52

What does the dotted line in the graph below indicate?

Answer 52

Increased volume from emphysema allows some air escape at the beginning of expiration when lungs are fullest.