Respiratory Phys: Exchange of Gases in Alveoli, Transport, Balance

Question 1

How is gas exchanges between alveoli and blood?

Answer 1

diffusion (from areas of greater to lesser partial pressures)

Question 2

What is the respiratory quotient?

Answer 2

ratio of CO2 produces to O2 consumed

RQ = VCO2 / VO2

Question 3

How much O is carried in the blood per min? CO2?

Answer 3

1L

2.8L

Question 4

What is the formula for partial pressure?

Answer 4

P = (atm pressure) x (fraction of molecules in dry air)

Question 5

amt of gas dissolved (Cx) =

Answer 5

partial pressure x solubility

Question 6

Why are alveoli kind of awesome for diffusion?

Answer 6

thin = short diffusion distance

Question 7

The flow of gas across a membrane is directly related to:

Answer 7

area available for diffusion
diffusion constant
partial pressure of gas

Question 8

The flow of gas across a membrane is inversely related to:

Answer 8

thickness of barrier

Question 9

Diffusion coefficient is directly related to

Answer 9

molecular weight

solubility

Question 10

Arterial partial pressures are determined by

Answer 10

alveolar partial pressures

Question 11

The partial pressure of CO2 in alveoli is directly related to:

Answer 11

CO2 production

Question 12

The partial pressure of CO2 in alveoli is inversely related to:

Answer 12

alveolar ventilation

Question 13

How does increased alveolar ventilation affect the partial pressure of CO2 in alveoli?

Answer 13

decreases, because freshly inspired air dilutes alveolar gas

Question 14

How does increased cellular metabolism affect the partial pressure of CO2 in alveoli?

Answer 14

increases, because more CO2 will enter blood per unit time

Question 15

If the production of CO2 is constant, what determines the partial pressure of CO2 in alveoli?

Answer 15

alveolar ventilation

Question 16

Describe hypoventilation in terms of PCO2

Answer 16

P-ACO2 increases because alveolar ventilation canot keep up with CO2 production

Question 17

Describe hyperventilation in terms of PCO2

Answer 17

P-ACO2 decreases because alveolar ventilation is excessive for nml CO2 production

Question 18

What is the driving stimulus for normal respiration?

Answer 18

arterial PCO2

Question 19

What factors determine P-AO2 (alveolar)?

Answer 19

1. PO2 of inspired air
2. alveolar ventilation
3. cellular oxygen consumption

Question 20

Alveolar gas equation:

Answer 20

P-AO2 = P-IO2 - (P-ACO2 / R)

where R = CO2 production / O2 consumption (~0.8)

Question 21

How does an increase in cellular consumption of O affect alveolar PO2?

Answer 21

decreases, greater concentration gradient so more O leaves alveoli

Question 22

Causes of hypoxemia?

Answer 22

1. high altitude
2. low alveolar ventilation
3. diffusion defect
4. ventilation/perfusion defect
5. R to L shunt

Question 23

What is hypoxemia?

Answer 23

lower than nml arterial PO2

Question 24

What does A-a gradient measure?

Answer 24

measure of whether O has equilibrated between alveolar gas and pulm capillary bed

Question 25

What is hypoxia?

Causes?

Answer 25

decreased O2 delivery to tissues

1. decreased blood flow
2. decreased O2 in blood (hypoxemia, anemia, CO poisoning, cyanide)

Question 26

What is hypercapnia?

Most common cause?

Answer 26

higher than nml arterial PCO2

hypoventilation

Question 27

At rest, blood spends about ___ sec in the lung capillary. It takes about ___ sec for the gases to equilibriate by diffusion.

Answer 27

.75

.3

Question 28

How does exercise affect pulm capillaries?

Answer 28

increased pulm vasc pressure opens up “many” pulm capillaries

Question 29

As blood leaves pulm capillaries, the PO2 and PCO@ are about the same as:

Answer 29

alveolar air

Question 30

How is O carried in tissues?

Answer 30

1. oxygen is physically dissolved (1.5% of O)

2. hgb bound

Question 31

What is cooperativity (in terms of hgb)?

Answer 31

reactions of 4 hgb subunits occur sequentially, with each binding facilitating the next

Question 32

What is cyanosis, in terms of hgb?

Answer 32

unsaturated hgb = purple; causes the bluish coloring in surface capillaries with low hgb sats

Question 33

Percent hgb saturation =

Answer 33

O2 bound to hgb / max capacity of O2 bound hgb

x100%

Question 34

What is demonstrated by hgb sat curve?

Answer 34

over 60 mmHg, changes in PO2 cause relatively little change in hgb sat
(e.g. 80mmHg ~ 95.9%; 60mmHg ~ 90%)

Question 35

Why is a hgb-O dissociation curve sigmoid shaped?

Answer 35

1. positive cooperativity

2. for steep portion, relatively small change in PO2 causes large changes in saturation

Question 36

O diffusion is governed ONLY by

Answer 36

gradient of dissolved portion of O in blood

Question 37

How does O bound to hgb contribute to blood PO2?

Answer 37

it doesn’t directly; however, it maintains gradient by capturing O2
*determines the total amount of oxygen that will diffuse

(adding hgb = O binds, more can diffuse into space)

Question 38

How does exercise affect the release of O from hgb to tissues?

Answer 38

1. increased blood floow

2. increased O2 demand creates a larger gradient, more O is extracted from the blood

Question 39

Decreased affinity of hgb for O causes a shift to the (right/left)
What factors facilitate unloading?

Answer 39

right

1. increased PCO2
2. decreased pH
3. increased temp
4. increased 2,3-DPG

Question 40

Increased affinity of hgb for O causes a shift to the (right/left)
What factors facilitate loading?

Answer 40

left

1. decreased PCO2
2. increased pH
3. decreased temp
4. decreased 2,3-DPG
5. fetal hgb

Question 41

How does metabolic activity affect hgb saturation?

Answer 41

increased metabolic activity increases CO2 production and increases [H] (lowers pH)

this DECREASES hgb affinity for O

Question 42

How does heat affect hgb saturation?

Answer 42

working muscle produces heat, which causes a conf change in hgb and facilitates release of O

Question 43

How does RBC’s glycolytic pathway affect hgb saturation?

Answer 43

increased glycolysis = increased levels of 2,3-DPG; this binds strongly to deoxy-hgb and lowers its O affinity (more O released to tissue)

Question 44

How does CO affect oxygen content of blood? Anemia?

Answer 44

CO binds 250x more strongly to hgb than O; this decreases the max O2 carrying capacity of blood

anemia = less hgb = decreased hgb O capacity

Question 45

3 mechanisms for CO2 transport in the blood:

Answer 45

1. dissolved in blood
2. carbamylation of proteins (carbamino-hgb)
   * 3. formation of bicarb via hydration in RBCs

Question 46

How is CO2 transported out of tissues?

Answer 46

1. CO2 is produced by tissues; it leaves cell and is dissolved in interstitial fluid
2. CO2 diffused into plasma, then into RBC where it is converted to bicarb
3. bicarb diffuses into plasma, and is exchanged for Cl- (maintains charge balance)
4. Cl- entrance into cell drags in H2O, which causes cell to swell

Question 47

How are H ions carried in blood?

Answer 47

within RBC, buffered by deoxy-hgb

Question 48

What is the Bohr effect?

Answer 48

• when tissues produce CO2, H and bicarb are produced by blood
• H production lowers pH, which shifts the dissociation curve to the right (facilitates O unloading)

Question 49

What are the differences between O2 and CO2 dissociation curves?

Answer 49

1. CO2 curve is much higher (more CO2 per L blood and more stored CO2)
2. CO2 curve is linear; O2 curve is sigmoidal
3. CO2 curve much steeper, big changes in CO2 content as PCO2 changes

Question 50

What is the Haldane effect?

Answer 50

When O2 sat of hgb is lower (more in deoxy form), H binding to hgb increased and CO2 carrying capacity increased

Question 51

pH =

H-H eq

Answer 51

6.1 + log [HCO3-]/0.03PCO2