Exam 4: Respiratory L3

Question 1

Transfer of gas across the blood gas barrier:
- Occurs via the process of _____

• Transfer of gas follows basic _____

Factors facilitating gas diffusion in the respiratory system:

1.

2.

3

Answer 1

Occurs via diffusion (passive)

Transfer of gas follows basic diffusion laws

Factors facilitating gas diffusion:

1. Large Surface Area of Alveoli (70 meters square = 750 square feet)
2. Short distance to travel
3. Gases with advantageous diffusion properties

Question 2

Capillary network is also ideal for gas exchange:

Capillary diameter:

RBC diameter:

Erythrocytes:

• Pass through capillaries in _______
• Average transit time is ___

Answer 2

Capillary diameter: less than ten um

RBC diameter: 7 um

RBCS:

Pass through capillaries in single file

Average transit time is roughly a second

Question 3

Total diffusion capacity for O2:
Combination of __ different diffusion constants:

Answer 3

12 different diffusion constants

Question 4

Fick’s Law of Diffusion Through Tissues:

(Parameters: Area, thickness, diffusion constant, partial pressure)

The amount of gas transferred is Proportional to what three things?

What is it inversely proportional to?

Answer 4

Diffusion through tissues:

Amount of gas transferred is proportional to Area, Diffusion Constant, and the Partial Pressure

Amount of gas transferred is inversely proportional to thickness

Question 5

What will happen to diffusion rate considering the following:

Pulmonary Edema

Collapsed Lung

High Altitude

Answer 5

PE: will cause an increase in thickness, and therefore a decrease in diffusion

Collapsed Lung: decrease in area, decrease in diffusion

High Altitude: Decrease in partial pressure, decrease in diffusion

Question 6

Both CO2 and O2 can rapidly diffuse across the alveolar barrier, but which one is better?

Answer 6

So, CO2 is better, but both will diffuse readily under normal conditions.

Question 7

Explain Diffusion Limited:

The amount of X carried into circulation is limited by ________.

Driving force will always be _____ than the rate at which molecules can pass through the barrier.

What are the two general examples of why molecules would be diffusion limited?

Draw the graph and figure for diffusion limited

Answer 7

Diffusion Limited:

• The amount of molecule X carried into circulation is limited by the diffusion across the alveolar membrane

Driving force will always be higher than the rate at which molecules can pass through the barrier.

Two main general examples:

1. Molecule simply can’t diffuse across the barrier
2. Molecule diffuses but then gets immediately converted to something or binds to something else and therefore no longer contributes to partial pressure

Question 8

Perfusion Limited:

• The amount of molecule X carried into circulation is limited by _____

Diffusion will quickly ______the driving force

The only way to get more molecule X into circulation is to _______.

Draw both figure and the graph

Answer 8

Perfusion Limited:
Amount of molecule X carried into circulation is limited by the rate of perfusion (blood flow through pulmonary capillaries)

Diffusion will quickly decrease the driving force

Only way to get more molecule X into circulation is to increase perfusion

Question 9

What is the different shape of the graph between Pressure as a function of time between diffusion limited and perfusion limited molecules

Answer 9

Question 10

Describe the following gases as perfusion limited or diffusion limited:

N2O (nitrous oxide)

CO (carbon monoxide)

O2 and Co2

Answer 10

N2O is perfusion limited (gas transfer is limited by the amount of blood perfusion the alveoli)

CO is DIFFUSION LIMITED (it binds rapidly to Hb and then doesn’t count as partial pressure anymore)

O2 and CO2 both bind to Hb, but with less affinity than CO, they are perfusion limited under normal circumstaces

Question 11

What happens to oxygen uptake along the pulmonary capillary under the following circumstances:

1. Exercise
2. Increased thickness of blood-gas barrier (like if you have fibrosis or edema)

Answer 11

1. Exercise: increased blood flow, but under normal circumstances you’re still okay because it’s perfusion limited and at 250 milliseconds you still are at PO2 of 100mmHg
2. Increased thickness of blood-gas barrier (fibrosis, or edema):

oxygen uptake may become diffusion limited

Question 12

Oxygen Uptake along the pulmonary capillary at lower alveolar PO2 (like at high altitude)

What does going to higher altitude do to the driving force/pressure gradient?

Severe exercise at high altitude can lead to _________.

Answer 12

Going to higher altitude will decrease the pressure gradient/driving force because you are decreasing the amount of PO2 in the air.

Severe exercise at high altitude can lead to diffusion impairment of oxygen transfer.

Question 13

What does D_L stand for?

How does it get measured in the clinic?

Answer 13

DL is the diffusion capacity of the lung

DL = V_CO / P_alveolarCO

CO is used because it diffuses rapidly and it is also not normally present in your blood

Single Breath DL of CO

Pt will breathe in CO (and a trace amount of He), hold for ten seconds, breathe out and then their volume of CO they breathe out will be measured. If diffusion of CO decreases, the graph will not be as steep of a drop off.

Question 14

Gas diffusion follows basic gas laws:

Diffusion is directly proportional to____

Diffusion is indirectly proportional to____

O2 and CO2 are normally ____ limited

Under extremes (high altitude or exercise) or disease, O2 can become _____

What is used to measure the total diffusion capacity of the lung?

Answer 14

Diffusion is directly proportional to: surface area, the pressure gradient, and also the diffusion constant

Diffusion is inversely proportional to thickness

O2 and CO2 are normally perfusion limited

Under extremes, or disease O2 can become diffusion limited

Single breath CO test is used to measure total diffusion capacity of the lung.

Question 15

What are the only arteries in the body that carry deoxygenated blood?

Answer 15

Pulmonary arteries

Question 16

Pulmonary arteries:
Total blood volume is like 500 mL

In the alveolar capillary network:

___ mL under resting conditions

___ during exercise

Answer 16

In alveolar capillary network:

70 mL under normal resting conditions

200 mL during exercise

Question 17

Pulmonary arteries:
- think wall, ____ smooth muscle

• ________ compliant than systemic arteries
• easily distendable

_____ pressure circulation

Driving Pressure: systemic vs pulmonary:

Answer 17

Pulmonary arteries:
- think wall, minimal smooth muscle

• 7x more compliant than systemic arteries
• easily distendable

LOW pressure circulation

Driving Pressure:
Systemic: 87 mmHg

Pulmonary: 6 mmHg

Question 18

What are the four factors influencing lung perfusion:

1.

2.

3.

4.

Answer 18

Factors Influencing Lung Perfusion:

• Pulmonary Vascular Resistance (PVR)
• Gravity
• Alveolar Pressure
• Arterial venous pressure gradient

Question 19

Pulmonary Vascular Resistance:

Explain/graph how PVR changes with increasing vascular pressure (in arteries and in veins)

What two mechanisms help with this process?

Answer 19

PVR decreases with increasing vascular pressure

MUCH more of a change in PVR with increasing pressure in the arterial side

Two Mechanisms:
1. Recruitment : opening of closed vessels and conducting in previously non conducting vessels

2. Distension: widening of open vessels

Question 20

For the blood vessels within the respiratory system:
Alveolar vessel : feels pressure from ____

Extra-alveolar vessel: feels pressure from

Answer 20

Alveolar Vessels: subject to pressure from alveoli

Extra-alveolar vessel: subject to pleural pressure

Question 21

Draw the graph showing how PVR changes with lung volumes for the alveolar and extraalveolar vessels

At which point is PVR the lowest?

Answer 21

PVR is the lowest at FRC (“steady state”)

At low lung volume, extra-alveolar vessels are subject to intrapleural pressure

At high lung volume, vessel stretching crishes alveolar vessels, pulls open extra-alveolar vessels

Question 22

Explain the affect that gravity has on distribution of pulmonary flow

Answer 22

Just like with ventilation,

most of the blood flow goes to the base instead of the apex.

Blood flow distrubution depends on posture

Difference between apex and base becomes less during exercise

Question 23

Both _____ and ____ are increased towards the base of the lungs

Answer 23

Both ventilation and pulmonary blood flow are increased towards the base of the lungs

Question 24

Explain the three zones within the lungs, the pressure gradient

Answer 24

Zone 1: PA > Pa> Pv (this zone only happens during hemorrhagic shock = alveolar dead space)

Zone 2: Pa > PA> Pv (equal pressure point situation where at some spot the alveolar pressure will impinge upon blood flow, causing the flow to travel down… “waterfall effect”)

Zone 3: Pa > Pv > PA high intrapleural pressure at the very base crushes the extra-alveolar vessels

Question 25

Hypoxic Vasoconstriction:
Reduction in _____ reduces blood flow

Explain how this is important at first breath after birth

Answer 25

Hypoxic Vasoconstriction:
Reduction in PAO2 reduces blood flow

There is a reduction in oxygen in your alveoli, the body then reroutes blood away from it by vasoconstriction (aka “hypoxic vasoconstriction)

Important at first breath after birth because there ends up being a dramatic decrease in PVR, and a vast increase in pulmonary blood flow after birth

Question 26

Fluid Balance:

Fluid leaving the vessels is due to ___ pressure

Fluid entering the vessels is due to ___ pressure

Why does left heart failure increase fluid in the lungs?

Answer 26

Fluid leaves vessels due to hydrostatic pressure

Fluid enters vessels due to oncotic pressure

Left Heart Failure, fluid backs up into pulmonary system, increasing hydrostatic pressure and therefore increasing the amount of fluid entering the lungs

Question 27

There is no net flow in or out of a blood vessel if what two things are equal?

In a healthy individual ______ pressure is greater than _____

Answer 27

If hydrostatic = oncotic pressure than there is no net flow in or out of the vessel

In a healthy individual, hydrostatic exceeds oncotic (constant flow from lung interstitual fluid into lymph)

Question 28

Fluid Balance:
If drainage rate from the interstitial space into the lymph is exceeded, what are the next two evens that happen?

Answer 28

If drainiage rate through interstitial space is exceeded

Then fluid will gather in the interstitial space

and then fluid will gather in the alveoli (major issues)

Question 29

Hypoxic vasoconstriction occurs when ____ is low

Answer 29

Hypoxic vasoconstriction occurs when PAO2 is low

Question 30

Pressures in the pulmonary circulation ______ systemic circulation

The capillaries are exposed to _____ and _____

Answer 30

Pressures in the pulmonary circulation are a lot less than in the systemic circulation

The capillareis are exposed to both alveolar pressure and intrapleural pressure

Question 31

Pulmonary Vascular Resistance (PVR) is ___ and falls even more when cardiac output increases (meaning _______). This is due to the mechanisms of ___ and ___.

Hypoxic pulmonary vasoconstriction shifts blood from ________ to _____ and is important at birth.

Answer 31

PVR is already low and falls even more when cardiac output increases (increased arterial pressure). This is due to the mechanisms of recruitment and distension.

Hypoxic Pulmonary Vasoconstriction shifts blood from poorly ventilated areas to well ventilated areas and is important at birth.

Question 32

Fluid movement across the capillary is governed by balance between _____ forces and ___ forces.

If drainage rate excees maximum lymph flow, ______ develops

Answer 32

Fluid movement across the capillaries is governed by the balance between hydrostatic forces and oncotic forces.

If drainage rate exceeds maximum lymph flow, then edema develops.

Question 33

What is the ratio of Volumes of Gas: Blood Volume

Ratio of Gas Flow: Blood Flow?

Answer 33

Volumes of gas to blood is 43:1

Flow Rate of Gas to Blood is 1:2

Question 34

What is the idea PO2 for the “perfect lung”

From the atmospheric air, to the air in the lungs, to the pressure in the tissue

Idea V to Q ratio?

Answer 34

“Ideal Lung”

Atm PO2 is 160 mmHg

Air in the lungs has PO2 of 100 mmHg

Tissues have PO2 of 40 mmHg

Ideal V:Q ratio is 1 to 1

Question 35

What does it mean when V/Q > 1

When V/Q < 1

What is the normal physiological V/Q ratio?

Answer 35

V/Q > 1 means ventilation exceeds perfusion

V/Q < 1 means perfusion exceeds ventilation

Normal V/Q ratio is approximately 0.8

Question 36

Explain the two extremes of a V/Q ratio:

The shunt alveolus vs the dead space alveolus

Answer 36

Question 37

Effect of Altering V/Q

As V/Q goes down, alveolar O2 and CO2 approach ______ (give values)

As V/Q goes up, alveolar O2 and CO2 approach _____ (give values)

Answer 37

As V/Q goes down, alveolar O2 and CO2 approach venous levels (O2= 40mmHg and CO2= 45 mmHg)

As V/Q goes up, alveolar O2 and CO2 approach atmospheric levels (PO2= 150 mmHg and PCO2 = 0)

Question 38

What is the highest V/Q ratio you can get?

Answer 38

Highest V/Q ratio is dead space alveolus

(blocking perfusion, it’s literally getting ventilated without little if any perfusion)

But yes, the V/Q ratio on the apex is greater than the V/Q ratio on the base, BUT the highest possible V/Q is dead space

Question 39

Veltilation and perfusion are elevated at the ___ of the lungs relative to the ____

Answer 39

Ventilation and perfusion are elevated at the base of the lungs relative to the apex.

Question 40

What is the V/Q ratio at your apex

What is the V/Q ratio at your base?

Answer 40

V/Q at apex is greater than one (approx 3)

V/Q at base is less than one, roughly 0.6

Question 41

The V/Q ratio determines the _____ in any single lung unit

The overall V/Q ratio of the normal lung is ___

There are considerable V/Q ratio differences across upright lung. V/Q is high at the ____ and low at the ___

Answer 41

V/Q ratio determines the gas exchange in any single lung unit

The overall V/Q ratio of the normal lung is 0.8

There are considerable V/Q ratio differences across the upright lung. V/Q is high at the apex and low at the base of the lung.

Question 42

V/Q mismatch and venous drainage (shunting) results in a PaO2 that is _______ than PAO2

Therefore, some level of V/Q mismatch happens in a normal physiological state

Answer 42

V/Q mismatch and venous drainage (“shunting”) results in a PaO2 that is slightly below PAO2

Question 43

Decrease O2 delivery to the tissue is called ____

Decreased O2 in arterial blood is called ____

Loss of blood flow is called _____

Answer 43

Decreased O2 delivery to the tissues is hypoxia

Decrease O2 in arterial blood is called hypoxemia

(generally PaO2 < 80mmHg is generally called hypoxemia)

Loss of blood flow is ischemia

Question 44

The clinical measure to diagnose the source of hypoxemia is _______

Answer 44

AaDO2 can help you figure out the source of hypoxemia

Question 45

Which two sources of hypoxemia have normal AaDO2:

-

-

Answer 45

The two H’s have normal AaDO2’s

• Hypoventilation
• High altitude

This is because the oxygen in the air being inspired is already low, so the O2 in arteries would be even lower, making the difference between the two normal

Question 46

Hypoxemia sources with increased AaDO2:

-

-

-

Answer 46

Hypoxemia sources with increased AaDO2

• V/Q mismatch
• Diffusion limitation
• Right to left shunt

Question 47

Normal AaDO2 is _____

How do you determine AaDO2:

Answer 47

Normal AaDO2 at room air is < 15mmHg

Determination of AaDO2:

PAO2 : alveolar gas eqn

PaO2/PaCO2: arterial blood gas analysis

Question 48

Explain how hypoventilation causes hypoxemia:

Alveolar PO2 depends on

• rate of removal from ____ (metabolic demand)
• Rate of replinishment from ____

If you stop breathing:
____ decreases and ____ increases

Answer 48

Hypoventilation:
Alveolar PO2 depends on rate of removal of oxygen by the blood, and then rate of replinishment from ventilation

If you stop breathing, alveolar PO2 decreases and Co2 will increase

Question 50

Hypoventilation:
Will the pt have an AaDO2 difference?

What will their PaCO2 and the PaOw look like?

Does additional O2 (increasing PO2 in the air) increase PaO2?

Answer 50

Hypoventilation:

Normal AaDO2

PaCO2 is high

PaO2 is low

this indicates hypoventilation

Additional PO2 will help increase PaO2

Question 51

Diffusion Limitation and hypoxemia

AaDO2 increased/decreased/or the same?

Reasons for diffusion limitation?

Answer 51

Diffusion Limitation:

Caused by edema, fibrosis, alveolar capillary block

think something is messing up with diffusion

AaDO2 will be increased for diffusion limited

Question 52

Shunt:
AaDO2 is _____

Additional O2 _______ increased PaO2 to the expected level

What is an anatomic shunt vs a physiological shunt?

Answer 52

Shunt:
AaDO2 is increased

Additional O2 will NOT increase the PaO2

Anatomic shunt: thesbian vessels and bronchial circulation drainage

Physiological shunt: venous mixture

Question 53

V/Q mismatch:

low V/Q ratio:

AaDO2 will be ______

Additional O2 will _______ PaO2

Answer 53

V/Q inequality:
most frequent reason for hypoexmia in patients in respiratory disorders

AaDO2 is increased

Additional O2 will increase PaO2

Question 54

Mechanisms for Compensation:

Explain Hypoxic Vasoconstriction and Bronchial Vasoconstriction

Answer 54

Hypoxic Vasoconstriction: instigated by LOW PAO2, the body will redirect the blood/perfusion to an area of higher ventilation

Bronchial Constriction: occurs with high PAO2, the bronchials will constrict in order to send air to places of good perfusion (classic example is a Pulmonary Embolism)

Question 55

Hypoxemia is abnormally low PO2 in arterial blood ( level is:______)

Causes for hypoxemia are :

Answer 55

Hypoxemia is abnormally low PaO2 (< 80mmHg)

Causes for hypoxemia : Normal AaDO2 will be hypoventilation and high altitidue….. Increased AaDO2 includes diffusion limitation, shunt (anatomical/physiological), and V/q mismatch

Question 56

______ is the most common cause of hypoxemia

_____ is the only cause of hypoxemia in which arterial PO2 does not rise to the expected level under 100% oxygen

_____ is useful to assess the cause for hypoxemia

Answer 56

V/Q mismatch is most common cause of hypoxemia

Shunt is the only cause of hypoxemia in which PaO2 will not be increased by breathing in 100% O2

AaDO2 is useful to assess the cause for hypoxemia