Lecture 24 - Diffusion

Question 1

What is the limitation of NO2 in the alveolus? Why?

Answer 1

Perfusion limited because there is no diffusion limitation and it equilibrates VERY fast

In order to obtain more NO2 in blood, you would need to perfuse the alveolus more

Question 2

Is NO2 normally found in blood?

Answer 2

NOPE (just used as an example here)

Question 3

What is the limitation of CO in the alveolus? Why?

Answer 3

Diffusion limited because it has a very high affinity to Hb (240x more than O2) and the only obstacle that is limiting more CO from entering into the bloodstream is therefore the properties of the membrane through which it is diffusing

CO will never equilibrate: it never exerts any back-pressure on more CO gas that is entering the blood

Question 4

What is the limitation of O2 in the alveolus? Why? Which portion of the curve does each represent?

Answer 4

Both perfusion and diffusion limited:

• In the first 0.25 seconds it takes for O2 to equilibrate, O2 is diffusion limited (slope)
• After 0.25 seconds, O2 is perfusion limited (plateau)

Question 5

Curve representing the diffusion or perfusion limitations of gases? How will the O2 curve be affected if the alveolar membrane is diseased? How will this affect the limitations of O2 in the alveolus?

Answer 5

• X-axis: time in capillary
• Y-axis: partial pressure

Slope would be flatter because it will take more time for O2 to pass the membrane and equilibrate => more diffusion limited

Question 6

3 factors that can challenge the diffusion of O2 into the pulmonary capillaries?

Answer 6

1. Exercise
2. Alveolar hypoxia
3. Thickening of the blood-gas barrier

Question 7

Describe how exercise can challenge the diffusion of O2 into the pulmonary capillaries.

Answer 7

Exercise => CO increases => RBC only spends 0.25 seconds in the pulmonary capillaries => if someone has a diffusion abnormality that causes O2 to equilibrate in more than 0.25 seconds, exercise will be difficult for them and they will become short of breath

Question 8

Under what circumstances could alveolar hypoxia occur?

Answer 8

High altitude

Question 9

How is diffusion of a certain gas measured?

Answer 9

Transfer factor = DL = A x D / T = V°gas / (P1 - P2)

Question 10

Transfer factor of CO?

Answer 10

DL = V°CO / P1 (since P2 is negligible) = V°CO / PACO

Question 11

How to measure diffusion capability of the lungs?

Answer 11

1. Have a person inhale a small amount of CO, hold their breathe for 10 seconds, and then exhale (CO is used to measure diffusion capacity because it is a gas that is purely diffusion limited)
2. Whatever amount of CO that went in but did not come out must have diffused into the blood stream
3. Measure volume of CO that was exhaled
4. Calculate the minute diffusion of CO, V°CO by multiplying measured volume by 6
5. Measure PaCO
6. Calculate the transfer factor of CO

Question 12

What are the 5 physiological causes of hypoxemia?

Answer 12

1. Low inspired PiO2
2. Hypoventilation
3. Diffusion limitations
4. Shunt
5. V/Q imbalance

Question 13

If the diffusion capability experiment was conducted on someone whose lungs are bleeding, aka there are RBCs in the alveoli, what would happen?

Answer 13

Less CO would be exhaled because the Hb molecules in the alveoli would take up some of it on top of the CO diffusing to pulmonary capillaries => diffusion capability is increased

Question 14

If the diffusion capability experiment was conducted on someone with CO in their blood, what would happen? What patients would have CO in their blood?

Answer 14

Less CO would diffuse to blood => diffusion capability is decreased

SMOKERS!

Question 15

What does hypoxemia mean?

Answer 15

Low PaO2

Question 16

Other name for V/Q imbalance?

Answer 16

Ventilation-perfusion mismatch

Question 17

How can you test if a patient with lung disease will need extra O2 when they fly on a plane?

Answer 17

Put a mask on them with only 15% O2 and see how they react

Question 18

How can hypoxemia due to low PiO2 be treated?

Answer 18

Give patient 100% O2

Question 19

What does hypoventilation mean?

Answer 19

Low ALVEOLAR minute ventilation, NOT total minute ventilation

Question 20

Hallmark of hypoventilation?

Answer 20

High PaCO2

Question 21

How can hypoxemia due to hypoventilation be treated?

Answer 21

Give patient 100% O2

Question 22

Hallmark of hypoxemia due to diffusion limitations?

Answer 22

PcO2 < PAO2

Question 23

How can hypoxemia due to diffusion limitations be treated?

Answer 23

Give patient 100% O2

Question 24

2 examples of diffusion abnormalities?

Answer 24

1. Thickened alveolar membrane

2. Decreased alveolar surface area

Question 25

What 2 diseases have thickened alveolar membranes?

Answer 25

1. Pulmonary fibrosis

2. Sarcoidosis

Question 26

What is hypoxemia due to shunt?

Answer 26

Venous blood bypasses reoxygenation and enters into arterial systemic circulation without coming in contact with a functioning alveolar-capillary membrane: perfusion, but no ventilation

Question 27

What are the 2 normal shunts of the body?

Answer 27

1. Bronchial circulation

2. Thebesian circulation

Question 28

Describe the shunt of the bronchial circulation.

Answer 28

Bronchial arteries carry oxygenated blood to cells of bronchi & trachea => blood becomes deoxygenated => some deoxygenated blood returns via pulmonary veins to the LA => deoxygenated blood mixes with oxygenated blood & pumped to body

Question 29

Describe the shunt of the Thebesian circulation.

Answer 29

Coronary arteries branch off of aorta => deliver oxygenated blood to heart => blood becomes deoxygenated => some deoxygenated blood is dumped into LA and LV via Thebesian veins => deoxygenated blood mixes with oxygenated blood & pumped to body

Question 30

Why is PaO2 = 95 mmHg?

Answer 30

Because of normal circulatory shunts

Question 31

What are 5 possible abnormal shunts? Describe each.

Answer 31

ANATOMIC SHUNTS: Right to left flow in heart:
1. Ventricular Septal Defect (VSD): a hole in the LV will cause the RV to get very strong. Over time, the RV will become a higher pressure system and push deoxygenated blood into LV

2. Atrial-Septal Defect (ASD): hole in atrial septum with RA pressure greater than LA pressure => deoxygenated blood in RA will pass into LA, then LV, and out to the entire body
3. Arterial-Venous Malformation (AVM): congenital abnormality where an artery goes right into a vein without a capillary in between
4. Patent Ductus Arteriosus (PDA): ductus arteriosus remains open, flow of deoxygenated blood from pulmonary trunk to aorta into systemic circulation

PHYSIOLOGIC SHUNTS:
4 Anatomical shunts
+
- Blood is coming in contact with alveolus but no gas exchange (e.g.: mucus blocking a bronchus)

Question 32

How can hypoxemia due to a shunt be treated?

Answer 32

NOT by giving the patient 100% O2 as blood will still escape being re-oxygentated

Would still help, but can’t fix the shunt issue like this

Question 33

V/Q ratio in shunt?

Answer 33

= 0

Question 34

What kind of patients have alveolar-venous malformations?

Answer 34

Patients with liver disease will have some in the lungs

Question 35

What is the A-a gradient? What is it normally?

Answer 35

PAO2-PaO2 due to shunts

Usually between 0 and 10 mmHg WHEN BREATHING ROOM AIR in a healthy person

Question 36

What is hypoxemia due to V/Q imbalance?

Answer 36

The rate of ventilation does not match the rate of perfusion: V/Q < 1

Question 37

Will there ever be a diseased stated where TOTAL V/Q > 1? Why?

Answer 37

NOPE, because perfusion will always move to another area of the lung to perfuse

Question 38

V/Q ratio of dead space?

Answer 38

= infinity

No perfusion, normal ventilation

Question 39

PAO2 and PACO2 as V/Q decreases?

Answer 39

PAO2 decreases and equilibrates to 40 mmHg

PACO2 increases and equilibrates to 45 mmHg

Question 40

PAO2 and PACO2 as V/Q approaches infinity?

Answer 40

PAO2 increases and equilibrates to 150 mmHg

PACO2 decreases and equilibrates to 0 mmHg

Question 41

What experiment can be done to visualize where most ventilation goes when a person inhales? Result? Why?

Answer 41

We have our patient inhale a given amount of nuclear-tagged gas, and then have a radiation counter behind them that will count where these particles go in the lung

Upon doing this experiment, we will get a distribution that shows that most ventilation occurs at the bottom of the lung

The reason for this is due to the fact that the alveoli at the top of the lung are stretched wide open because the weight of the lungs hang down and therefore pulls them open so since they are already full of air they do not have a lot of the air flow during respiration

Question 42

Describe the effect of gravity on pulmonary blood flow.

Answer 42

Lungs are 25 cm long and blood flow enters them at about the middle of their height, so with gravity:

• Blood flow is the greatest at the bottom of the lung due to gravity
• Blood flow at the top of the lung is lowest due to collapse of vessels

Question 43

In graphs showing the perfusion and ventilation from top of lung to bottom of lung, which slope is steepest?

Answer 43

Perfusion slope

Question 44

What does the fact that most ventilation occurs at the bottom of the lung mean a for regional pressure gradient?

Answer 44

One exists inside the lung with intrapleural pressure at the top of the lungs being more negative than at the bottom

Question 45

If both ventilation and perfusion are plotted on one graph with x-axis as bottom to top of lung, at what point would both curves intersect?

Answer 45

At V/Q = 1 around the 3rd rib

Question 46

V/Q ratio at top of lung? What to note?

Answer 46

> 1

BUT summation of V/Qs in all of the regions of the lung will be 1 in a healthy individual

Question 47

V/Q ratio at bottom of lung? What to note?

Answer 47

< 1

BUT summation of V/Qs in all of the regions of the lung will be 1 in a healthy individual

Question 48

What are West Zones of the lung?

Answer 48

They divide the lung in 3 regions based on difference in PA, Pa, and Pv:

1. Zone 1 = apex: ventilation is better than perfusion so PA > Pa > Pv
2. Zone 2 = middle: Pa > PA > Pv
3. Zone 3 = bottom: perfusion is better than ventilation so Pa > Pv > PA

Question 49

In which West Zone of the lung can you insert a Swan-Ganz catheter? Why? What happens if you place it in the other 2 zones?

Answer 49

Zone 3 only because only zone where venous pressure is greater than the alveolar and the balloon will stay open and keep capillary occluded

• Zone 1: only measuring airway pressure because capillaries are collapsed
• Zone 2: balloon will not stay open and you will only measure airway pressure because PA>Pv

Question 50

A-a gradient for low FiO2 state?

Answer 50

Normal

Question 51

A-a gradient for hypoventilation state?

Answer 51

Normal

Question 52

A-a gradient for diffusion limitation state?

Answer 52

Abnormal: elevated

Question 53

How can hypoxemia due to V-Q mismatch be treated?

Answer 53

100% O2 => ALL PAO2 will rise, including in the alveoli that have ventilation issues

Question 54

A-a gradient for V-Q mismatch state?

Answer 54

Abnormal: elevated

Question 55

A-a gradient for shunt state?

Answer 55

Abnormal: elevated

Question 56

If the diffusion capability experiment was conducted on someone with anemia what would happen?

Answer 56

Less CO would diffuse to blood because back pressure would build up in the blood due to low Hb => diffusion capability is decreased

Question 57

Out of the 5 physiological causes of hypoxemia, which ones will be corrected to over 500-600 mmHg by increasing FiO2?

Answer 57

All, except for shunt