Lectures 9 & 10: Pulmonary (Exam II)

Question 1

What is atmospheric pressure?

Answer 1

760mmHg or 1atm

Question 2

What is P_IP?

Answer 2

• Pleural Pressure = -5cmH₂O

Question 3

What is P_A?
What does it normally measure?

Answer 3

Alveolar pressure = -1(inspiration) to +1(expiration) cmH₂O normally.

Question 4

What is P_EL ?

Answer 4

Elastic recoil pressure: the tendency of the inflated lung to recoil back from its inflated state to a deflated state.

(+5 cmH₂O)

Question 5

What is another term for P_EL?

Answer 5

P_ER

Question 6

What is a transmural pressure?

Answer 6

The difference of two pressures that have a wall separating them.

Question 7

What is the formula for P_TP (Transpulmonary Pressure)?

Answer 7

P_TP = P_A - P_IP

Question 8

If cut, what would occur to the ribs? Why?

Answer 8

Ribs would pop out due to the elastic forces of the cartilage and intercostal muscles.

Question 9

Given P_A= 0 and P_IP = -5, what would P_TP be?

Answer 9

P_TP = P_A - P_IP

P_TP = 0 - (-5) = +5 cmH₂O

Question 10

A pneumothorax would cause what pressure to disappear?

Answer 10

P_IP

Question 11

When do the lungs start to degrade?

Answer 11

At 20yrs old

Question 12

Which of the following lung volume/capacity diagrams would be indicative of someone standing and which would be indicative of someone laying supine? Why?

Answer 12

• Left is standing:
• Right is supine: supine will ↑abdominal pressure on the diaphragm and reduce FRC.

Question 13

Why is pre-oxygenation so important for induction?

Answer 13

Supine positioning decreases FRC. Pre-oxygenation counteracts this loss of FRC.

Question 14

What would be indicated by 2 on the figure below?

Answer 14

V_T = 0.5L

Question 15

What would be indicated by 1 on the figure below?
What is this?

Answer 15

• Inspiratory Reserve Volume (IRV) = 2.5L
• The inspiratory capability of the patient beyond V_T.

Question 16

What would be indicated by 11 on the figure below?
How would this be calculated?

Answer 16

• Inspiratory Capacity (IC) = 3L
• IRV + V_T = IC

Question 17

What would be indicated by 5 on the figure below?

Answer 17

Maximal Inspiration

Question 18

What would be indicated by 3 on the figure below?
What is this?

Answer 18

• Expiratory Reserve Volume (ERV) = 1.5L
• The amount of air that can be exhaled purposefully by using the abdominal muscles to push up on the diaphragm.

Question 19

What would be indicated by 9 on the figure below?
What is this and how is it calculated?

Answer 19

• Vital Capacity (VC) = 4.5L
• VC = IRV + V_T + ERV
• This is the “working volume” of the lungs (the total amount of air we are capable of moving).

Question 20

What would be indicated by 6 on the figure below?

Answer 20

Point of maximal expiration

Question 21

At what point would there no longer be any air in the lungs at all?

Answer 21

7

Question 22

What would be indicated by 4 on the figure below?
What is this?

Answer 22

• Residual Volume (RV) = 1.5L
• Air left in the lungs after maximal expiration (This can’t be exhaled out)

Question 23

What would be indicated by 10 on the figure below?
What is this and how is it calculated?

Answer 23

• Functional Residual Capacity (FRC) = 3L
• FRC = ERV + RV
• This is the amount of air the lungs as a baseline

Question 24

What lung volume/capacity keeps the lungs open and is a buffer against periods of apnea?

Answer 24

FRC

Question 25

What would be indicated by 12 on the figure below?
What is this and how is it calculated?

Answer 25

• Total Lung Capacity (TLC) = 6L
• The total volume of both lungs at their max.
• TLC = IC + FRC

Question 26

As one gets older, the loss of ____ necessitates the increasing of expiratory time.

Answer 26

P_ER

Question 27

How long is a typical respiratory cycle?
How long is inspiration?
Expiration?

Answer 27

• 5 seconds
• 2 seconds
• 2 seconds

There’s supposed to be a 1 second pause in-between inspiration and expiration.

Question 28

What is depicted below?

Answer 28

V_T during a respiratory cycle

Question 29

What is depicted in the figure below?

Answer 29

Intrapleural Pressure (P_IP) in cmH₂O during the respiratory cycle.

Question 30

What causes the change in chest pressure at 2 seconds in the figure below?

Answer 30

Diaphragm relaxation.

Question 31

What is depicted in the figure below?

Answer 31

Airflow in L/s during the respiratory cycle

Question 32

What is depicted in the figure below?

Answer 32

Alveolar pressure (P_A) in cmH₂O during the respiratory cycle.

Question 33

Describe what is occurring the figure below.

Answer 33

Changes in FRC according to positional change.

Question 34

If during an expiration the P_TP = -7 cmH₂O then what would P_EL equal?

Answer 34

+ 7 cmH₂O

Question 35

What will occur when P_ER is greater than P_IP?

Answer 35

Lungs will recoil back to baseline

Question 36

When is P_A a positive number?

Answer 36

During expiration

Question 37

When would P_A = 0 cmH₂O ?

Answer 37

At the end of expiration

Question 38

As P_IP decreases (becomes increasingly negative) so does ______.
Why is this?

Answer 38

• P_A
• Negative intrapleural pressure causes expansion, pulling out the alveoli and making the alveolar pressure negative as well, thus drawing in fresh air.

Question 39

When does the most negative P_A occur?
What is the the most negative P_A?

Answer 39

P_A = -1 cmH₂O at 1second of inspiration.

Question 40

When does the fastest inspiratory airflow occur?

Answer 40

At 1 second of inspiration = most negative P_A = greatest inspiratory flow.

Question 41

What lung zone is depicted by 1 in the figure below?
What pressures would be exhibited by this lung?

Answer 41

• Zone 1
• P_A > P_a > P_v

Question 42

How much blood flow is seen in a Zone 1 lung? Who has Zone 1 lungs?

Answer 42

• Very little to no blood flow. Zone 1 lungs are a pathologic condition.

Question 43

What lung zone is depicted by 2 in the figure below?
What pressures would be exhibited by this lung?

Answer 43

• Zone 2
• P_a > P_A > P_v

Question 44

What lung zone is depicted by 3 in the figure below?
What pressures would be exhibited by this lung?

Answer 44

• Zone 3
• P_a > P_v > P_A

Question 45

What lung zone exhibits pulsatile blood flow?
What lung zone exhibits non-pulsatile continuous blood flow?
What is the reasoning for the difference?

Answer 45

• Pulsatile = Zone 2
• Continuous = Zone 3
• Gravity: ↑ pressure = ↑ perfusion

Question 46

What lung zone is depicted by 1 in the figure below?

Answer 46

Zone 4

Question 47

What causes the decrease in blood flow at the very bottom of the lung depicted by the red circle in the figure below?

Answer 47

• Zone 4 decreased blood flow occurs from compression from the lung above as well as the diaphragm.

Question 48

What would occur with alveolar capillaries during inspiration?

Answer 48

↑ capillary length & ↓ capillary diameter = ↑ alveolar vascular resistance

Question 49

What would occur with alveolar capillaries during expiration?

Answer 49

↓ capillary length & ↑ capillary diameter = ↓ alveolar capillary resistance.

Question 50

What would occur with extra-alveolar vessels during inspiration?

Answer 50

↑ vessel diameter = ↓ extra-alveolar vascular resistance

Question 51

What would occur with extra-alveolar vessels during expiration?

Answer 51

↓ vessel diameter = ↑ extra-alveolar vascular resistance.

Question 52

At what volume does the lowest pulmonary vascular resistance occur?

Answer 52

Lowest PVR occurs at FRC

Question 53

At what volume does the highest pulmonary vascular resistance occur?

Answer 53

Highest PVR occurs at Residual Volume (RV)

Question 54

At what volume is alveolar volume at its greatest?

Answer 54

TLC (Total lung capacity)

Question 55

At what volume is extra-alveolar volume at its greatest?

Answer 55

RV (Residual volume)

Question 56

What general relationship do pulmonary blood flow and PVR have?

Answer 56

Inverse (ex. ↑blood flow = ↓PVR)

Question 57

Which of the following graphics below is indicative of recruitment?
Distension?

Answer 57

Question 58

How do recruitment and distension of pulmonary vasculature result in decreased PVR?

Answer 58

• Recruitment = more parallel pathways
• Distension = ↑ vessel diameter

Question 59

What conditions/agents/hormones/etc will cause a increase in PVR?

Answer 59

• SNS neurotransmitters (NE, Epi, α-agonists, etc.)
• Inflammatory mediators
• Alveolar hypoxia
• Alveolar hypercapnia
• Acidotic mixed venous blood

Question 60

What inflammatory mediators will increase PVR?

Answer 60

• Thromboxane
• Angiotensin
• Histamine

Question 61

What conditions/agents/hormones/etc will decrease PVR?

Answer 61

• PSNS activity
• ACh
• β-agonists
• PGE₁
• PGI₂
• Nitric Oxide
• Bradykinin

Question 62

What effect does acetylcholine have on the lungs?

Answer 62

• Blood vessel dilation (↓PVR)
• Airway constriction

Question 63

What is the partial pressure of O₂ in dry atmospheric air?

Answer 63

159mmHg

O₂ pressure = 760mmHg x [.21]

Question 64

What is the formula for partial pressure?

Answer 64

Partial pressure = total pressure x [gas]

Question 65

What is the partial pressure of 100% humidity? Why does this matter?

Answer 65

47 mmHg : important due to displacing effect on other gasses.

Question 66

Calculate the partial pressure of inspired humidified O₂ .

Answer 66

P_IO₂ = F_IO₂ (P_B - P_H₂O )

P_IO₂ = 0.21 (760mmHg - 47mmHg)

P_IO₂ = 150 mmHg

Question 67

What would occur with intra-alveolar O₂ and CO₂ levels if a blocked airway was overcome with 100% FiO₂ and positive pressure?

Answer 67

↑O₂ & ↑CO₂ from “trapping”.

Question 68

What would normal P_AO₂ be?
Why not 150mmHg as this is what’s being delivered?

Answer 68

P_AO₂ = 100mmHg due to O₂ absorption into the vasculature.

Question 69

What is normal PvCO₂?
What is normal PaCO₂?

Answer 69

• PvCO₂ = 45mmHg
• PaCO₂ = 40mmHg

Question 70

How much CO₂ is delivered to the alveolus via the airways?
What is normal P_ACO₂?
Why is this?

Answer 70

• 0 mmHg
• 40mmHg
• CO₂ extraction from blood vessels to alveolus for exhalation.

Question 71

If normal O₂ delivery to the tissues is 20mLO₂/dL and the normal return is 15mLO₂/dL then ΔmLO₂ = 5 mLO₂/dL.

What would the the ΔmLCO₂ be in a normal healthy person?
Why the discrepancy?

Answer 71

4.5 mLCO₂ due to increased hydrophilicity of CO₂.

Question 72

What would occur with a very negative P_ISF in the pulmonary interstitium?

Answer 72

Flash Pulmonary Edema

Question 73

What conditions were discussed in class that can cause pulmonary edema?
Why would each do so?

Answer 73

• LV failure causes ↑P_CAP = pulm edema
• Colloid loss causes ↓ π_CAP = pulm edema

Question 74

What does Q typically mean?

Answer 74

Blood flow (perfusion)

Question 75

What is K_f?
What is it used for?

Answer 75

• Capillary Filtration Coefficient.
  Describes how permeable the capillaries are.
• K_f is used to convert mmHg to blood flow.

Question 76

What is the Starling Capillary Equation?

Answer 76

Q_f = K_f [(P_CAP - P_ISF) - σ(π_CAP - π_ISF)]

Question 77

An increase in K_f would correlate with an increase in _______ _________.

Answer 77

capillary permeability

Question 78

What is HPV (hypoxic pulmonary vasoconstriction) ?

Answer 78

Mechanism by which poorly ventilation portions of the lung are vascularly bypassed through arterial constriction.

Question 79

Where in the figure below does HPV occur?

Answer 79

Question 80

How can HPV contribute to right ventricular heart failure?

Answer 80

HPV will vasoconstrict thus increasing PVR = increased RV afterload.

Question 81

What concept is being described with the diagram in the figure below?

Answer 81

Alveolar size contrasted with blood vessel dilation/perfusion.

Question 82

Where would we expect greater air flow to occur in the diagram below? (assume an inspiration from FRC)
Why?

Answer 82

Alveoli in apex are more full, therefore air will preferentially fill the bottom portion of the lung.

Question 83

Where would we expect greater air flow to occur in the diagram below? (assume an inspiration from RV)
Why?

Answer 83

Positive P_TP at the base of the lungs would cause air to preferentially fill the apex of the lung prior to the base.

Question 84

What pulmonary homeostatic mechanism prevents underutilized perfusion to underventilated arteries?

Answer 84

HPV (Hypoxic Pulmonary Vasoconstriction)

Question 85

When exercising, is it better to increase respiratory rate or depth of breathing to ensure adequate O₂ inhalation?
Why?

Answer 85

Depth of breathing: this is because V_A is increased with no wasted air on V_D.

Question 86

In the picture below, what is denoted by:

• 150mls?
• 350mls?

Answer 86

• V_D = Dead space volume = 150 mLs
• V_A = Alveolar gas volume = 350mLs

Question 87

What does n represent in our pulmonary equations?

Answer 87

n = breaths per min

Question 88

How many breaths per minute are taken under normal conditions?

Answer 88

12bpm

Question 89

What is V̇_T?

Answer 89

• V̇_T = volume of air inhaled every minute by the lungs.
• V̇_T = (n)V_T = 6L

Question 90

How can alveolar minute volume be calculated?

Answer 90

V̇_A = V̇_T - V̇_D

4200mLs = 6000mLs - 1800mLs

Question 91

What is V_E and what is it used for?

Answer 91

V_E = minute expiration volume: used to approximate V̇_T

Question 92

V̇_T = _____ = V_T x n

Answer 92

V_E

Question 93

What percentage of TLC is RV usually?

Answer 93

20%

Question 94

At which of the following transpulmonary pressures would you expect to find the easiest to fill alveolus (at FRC)?

A. P_TP = 0-10 cmH₂O
B. P_TP = 10-20 cmH₂O
C. P_TP = 20-30 cmH₂O
D. P_TP = 30-40 cmH₂O

Answer 94

A. P_TP = 0-10 cmH₂O

Question 95

Where would you expect to find a more positive P_IP in the lungs?

Answer 95

Base

Question 96

Where would you expect to find a more negative P_IP in the lungs?

Answer 96

Apex

Question 97

Where would you expect to find a higher P_TP in the lungs?

Answer 97

Apex

Question 98

Where would you expect to find a lower P_TP in the lungs?

Answer 98

Base

Question 99

Two circles are indicated below, which of these would be indicative of a higher lung compliance?

Answer 99

Green circle (steeper curve)

Question 100

Would a P_TP of 30 cmH₂O be more or less compliant than a P_TP of 10 cmH₂O?

Answer 100

30 cmH₂O is less compliant than 10 cmH₂O.

Question 101

Inspiration from FRC means air goes to the _____ of the lung preferentially.

Answer 101

base

Question 102

Inspiration from RV means air goes to the _____ of the lung preferentially.

Answer 102

apex/top

Question 103

Where is the intrapleural pressure located?

If you were to point to an exact space where the negative P_IP is located, where is that?

Answer 103

In-between the visceral and parietal pulmonary pleura.

Question 104

How is alveolar pressure calculated?

Answer 104

P_A = P_IP + P_ER

Question 105

How is transmural pressure calculated?

Answer 105

P_TP = P_A - P_IP

Ex. P_TP = 0 - (-5) = +5