Oxygen and Carbon Dioxide

Question 1

What is partial pressure?

Answer 1

the pressure of an individual gas in a given volume at a constant temperature

Question 2

Total pressure is divided into partial pressure of O2 and N2. What are the relative percentages of each that make up total pressure?

Answer 2

pO2 = 160 mm Hg = 21% total pressure

pN2 = 600 mm Hg = 79% total pressure

Question 3

describe the diffusion of gases in ventilation

Answer 3

the respiratory system functions to maintain the partial pressure of O2 and CO2, so O2 will diffuse into capillaries from alveoli, and CO2 will diffuse into alveoli from capillaries

Question 4

3 differences between alveolar air vs atmospheric air

Answer 4

alveolar air has less O2, more CO2, and is humidified

Question 5

what is the function of humidifying air as it is drawn through the respiratory passages?

Answer 5

water vapor at normal body temp is 47mm Hg, so when it is added to the mix of gas in the alveoli, it serves to dilute the other gases

Question 6

what is the mix of gases found in the alveoli?

Answer 6

14% O2
75% N2
5% CO2
6% H2O

Question 7

describe the solubility of CO2 and O2 in blood

Answer 7

CO2 is highly soluble in blood, O2 is less so

Question 8

Name 5 things that affect the rate of diffusion of a gas

Answer 8

1) solubility of gas in the fluid
2) surface area of the barrier
3) distance of diffusion (membrane thickness)
4) molecular weight of gas
5) temperature (irrelevant because body temp is constant)

Question 9

why is aqueous diffusion the limiting factor?

Answer 9

respiratory gases are highly soluble in lipids (cells/tissue)

Question 10

what is tidal volume?

Answer 10

normal volume of air displaced between inhalation and exhalation; “renewed” air

Question 11

what is functional residual capacity?

Answer 11

the volume of air that stays in the lungs; it acts as a sort of buffer that prevents sudden changes in the alveolar gas mix

Question 12

what 2 factors control the amount of oxygen in the alveoli at a given time?

Answer 12

ventilation from breathing and rate of absorption from the blood

Question 13

As metabolism increases, what happens to blood O2 and CO2?

Answer 13

O2 decreases and CO2 increases

Question 14

as metabolism increases, what happens to the O2 and CO2 partial pressure of the lung?

Answer 14

lung O2 partial pressure decreases and CO2 partial pressure increases

Question 15

What is VA/Q?

Answer 15

• the ventilation (VA) perfusion (Q) ratio

- can be expressed as a function of partial pressures of O2 and Co2 in an alveolus

Question 16

what happens when VA/Q = 0?

Answer 16

• no air reaching the alveolus; 0/Q = 0
• partial pressure of both gasses in the alveolus equilibrate with that of the pulmonary blood
• no respiration takes place

Question 17

what happens when VA/Q = infinity (VA/0)?

Answer 17

• no blood perfuses an alveolus, so no gas exchange happens

- no respiration takes place

Question 18

what is non-perfused blood called?

Answer 18

shunted blood

Question 19

what happens when VA/Q approaches 0?

Answer 19

• the physiologic shunt occurs

- the amount of shunted blood that passes through the pulmonary circulation per minute = physiologic shunt

Question 20

what happens when the VA/Q ratio is lower than normal?

Answer 20

• supply is not sufficient to oxygenate all perfusion

- result is shunted blood

Question 21

what happens when the VA/Q ratio moves away from 0?

Answer 21

• physiologic dead space

- not all inspired air is available for gas exchange (that air is called physiological dead space air)

Question 22

what happens when the VA/Q ratio is greater than normal?

Answer 22

• physiological dead space

- supplied ventilation is greater than perfusion

Question 23

What equation describes physiologic dead space

Answer 23

the Bohr equation

Question 24

In what part of the lungs is a physiologic shunt normal?

Answer 24

• lower portion of the lungs due to greater blood flow and slightly insufficient ventilation
• can be minimized by exercise

Question 25

in what part of the lungs is a physiologic dead space normal?

Answer 25

• top portion of the lung due to lower blood flow
• can be minimized by exercise
• *physiologic dead space actually also exists in the lower portion of the lung

Question 26

blood leaves the alveoli with what partial pressure of O2?

Answer 26

104 mm Hg

Question 27

what is the average arterial partial pressure of O2?

Answer 27

95 mm Hg

Question 28

what is the average venous partial pressure of O2?

Answer 28

40 mm Hg

Question 29

partial pressure of O2 in the tissues is around 23 mm Hg. Why is this not problematic?

Answer 29

intracellularly, only 1-3 mm Hg are generally required to support cell processes

Question 30

what component of RBCs helps make O2 more soluble?

Answer 30

hemoglobin

Question 31

how much of all O2 in the blood is bound to hemoglobin?

Answer 31

97%

the rest is freely dissolved

Question 32

describe hemoglobin-oxygen disassociation

Answer 32

high partial pressure of O2 favors hemoglobin binding of O2; low partial pressure of O2 favors disassociation of O2.

Question 33

the total content of O2 in the arteries is dependent on what?

Answer 33

the partial pressure of free O2 (the amount of O2 hemoglobin is carrying)

Question 34

what form is oxygen in when it binds to hemoglobin?

Answer 34

elemental (diatomic) form; as O2, so 2 oxygens bind at each of the 4 hemoglobin sites

Question 35

describe the cooperative binding of O2 to hemoglobin

Answer 35

• for each site occupied, the affinity of the following site for oxygen is increased.
• the opposite is true of hb release of O2: for each O2 that disassociates, the easier it is for the following molecules to disassociate

Question 36

for the delivery of oxygen, is increasing hg/saturation of hg more or less powerful than increasing the partial pressure of O2 in blood?

Answer 36

increasing hg or saturation of hb is more powerful

Question 37

what is the utilization coefficient?

Answer 37

• the percentage of blood that gives up its O2

- at rest, this is usually 25% but can increase to 85% during exercise

Question 38

describe the O2 disassociation curve

Answer 38

• as partial pressure of O2 exposed to hb increases, the saturation of hb increases
• eventually, hb will reach total saturation; this gives the curve a sigmoidal shape
• the steep section of the curve represents cooperative binding
• hb acts as a buffer to resist changes in tissue PO2

Question 39

T or F:

fetal hemoglobin tends to bind more O2

Answer 39

true

Question 40

describe the Bohr effect

Answer 40

• the affinity of hemoglobin’s binding to O2 is inversely related to acidity and the concentration of CO2
• in other words, more O2 is released in tissues with high CO2 and low pH

Question 41

carbon dioxide is ___ times more soluble in blood than O2

Answer 41

20 times more soluble

Question 42

what percent of CO2 is converted to carbonic acid, and what enzyme catalyzes that reaction?

Answer 42

• 93%; the rest is dissolved directly into the blood

- catalyzed by carbonic anhydrase

Question 43

what happens to the 5-7% of CO2 that dissolves directly into the blood?

Answer 43

• it can bind to plasma proteins or enters RBCs and binds hg
• forms carbaminohemoglobin
• as RBCs pass through O2 rich pulmonary circulation, CO2 disassociates from hg and O2 takes its place

Question 44

describe carbon monoxides affinity for hg

Answer 44

• CO has a great affinity for hg compared to CO2 or O2 and is thus, retained by the hg
• ventilation with O2 can force off the CO

Question 45

describe the difference between the haldane effect and the bohr effect

Answer 45

• haldane effect states that deoxygenated blood has an increased ability to carry CO2 and oxygenated blood carries less CO2
• bohr effect states that the affinity of hg’s binding to O2 is inversely related to acidity and the concentration of CO2