Gas Transport

Question 1

what is the difference between inspired (tracheal) air and atmospheric air?

Answer 1

• when you breathe in, it becomes saturated with water vapor
• the water vapor pressure varies with temperature

Question 2

how does vapor pressure change in the respiratory system?

Answer 2

• at normal body temp, vapor pressure = 47mmHg
• when you increase temperature, you increase the partial pressure of water and vice verse

Question 3

how do the partial pressures of oxygen and nitrogen change with vapor pressure being added?

Answer 3

they decrease! now have to factor in an additional pressure

Question 4

how does the air change in the alveoli?

Answer 4

• this is the site of gas exchange, so O2 is absorbed into the blood and CO2 is added to the alveolar air
• the uptake of CO2 in the alveoli is not a drastic amount but a lot of O2 is absorbed into the blood

Question 5

what is Henry’s law of dissolved gases? what does it tell us?

Answer 5

• the amount of gas that dissolves in a given volume of liquid is directly proportional to the partial pressure of that gas
• when there is a gas-liquid interface, the gas will dissolve into the liquid
• if you increase the pressure, there will be more diffusion and increase the concentration of dissolved gas
• this can be used to determine the amount of oxygen transported in the plasma

Question 6

what is the structure of hemoglobin? why is it important?

Answer 6

• has 4 chains, iron, heme – 4 oxygen binding sites on each molecule of Hb
• depending on how many binding sites are occupied by oxygen determines the amount of oxygen transported by the blood

Question 7

when fully saturated with oxygen, how much oxygen binds to 1 gram of Hb?

Answer 7

1.34 mL of O2 is bound = maximum per gram

Question 8

what is oxygen capacity?

Answer 8

• the maximal amount of oxygen that will combine with the Hb of that blood
• varies with the Hb concentration of the blood
• O2 only binds to Hb
• important for understanding anemias (low Hb = low O2)

Question 9

what is normal oxygen capacity?

Answer 9

• the normal amount of oxygen in the blood based on normal Hb levels
  normal Hb = 15 grams/dLof blood
  normal O2 capacity = 20.1 mL O2/dL of blood

Question 10

what is oxygen saturation? (SO2)

Answer 10

• the percentage of the oxygen capacity that is actually occupied by oxygen
  (how much is bound out of how much is there)
• arterial ≈ 100%
• venous ≈ 75%

Question 11

what is Hb bound oxygen content?

Answer 11

the concentration of oxygen that is bound to hemoglobin out of the maximal amount that you can hold (how many of the binding sites are full with O2)

Question 12

what is total oxygen content?

Answer 12

• the total amount of oxygen dissolved in the blood (unbound) + the total amount of oxygen bound to hemoglobin
• sample questions on 136-139

Question 13

what is the oxygen-Hb dissociation curve and what does it tell us?

Answer 13

• a graph that shows the relationship between the pressure of oxygen in blood, hemoglobin saturation, and Hb-O2 content
• when there is a higher pressure of oxygen (more of it) and higher hemoglobin saturation, there is a higher Hb-O2 content
• must have enough hemoglobin and oxygen to induce maximal binding between the two
• sigmoid relationship that results from heme-heme interactions

Question 14

what happens to total oxygen content when oxygen partial pressure changes?

Answer 14

• increase PO2 = increase blood oxygen content bound to Hb
• there is a small amount of dissolved (unbound) O2

Question 15

why is the oxyhemoglobin dissociation curve important for understanding gas transport and exchange?

Answer 15

• it tells us the relationship and binding affinity of Hb to oxygen in different parts of the body
• in the tissues, there is a lower binding affinity for O2, which allows for gas exchange – as you change the pressure, there are bigger changes to the saturation
• in the lungs, the affinity is much higher and small changes to pressure don’t affect the amount of bound O2 as significantly

Question 16

what is the physiologic significance of the S-shape of the oxyhemoglobin dissociation curve?
- basically the same thing as the last card but in Edinger’s terms

Answer 16

Question 17

how does arterial oxygen and HbO2 content compare to that of venous?

Answer 17

Question 18

what happens to the Hb-O2 binding when you change the pH?

Answer 18

if you increase the concentration of H+ = decrease saturation of Hb-O2 at higher O2 pressures and vice verse
– lower pH = shift right
– higher pH = shift left

Question 19

what happens to the Hb-O2 binding when you change the temperature?

Answer 19

if you increase temperature = decrease saturation of Hb-O2 at higher O2 pressures and vice verse
– higher temp = shift right
– lower temp = shift left

Question 20

what happens to the Hb-O2 binding when you change the pressure of CO2?

Answer 20

if you increase CO2 = decrease saturation of Hb-O2 at higher O2 pressures and vice verse
– higher CO2 = shift right
– lower CO2 = shift left

Question 21

why does CO2, H+, and temperature concentration have this affect on Hb-O2 binding?

Answer 21

• because these are consequences of tissue metabolism
• when you increase metabolism, the are products made by it and need to be rid of or taken else where
• O2 needs to go the the tissues so all of this is exchanged
• so blood looses O2 and gains the metabolism byproducts

Question 22

what is anemia and polycythemia?

Answer 22

anemia = less than normal Hb and less RBCs
polycythemia = more than normal Hb and RBCs

Question 23

what is the effect of anemia and polycythemia on the Hb-O2 dissociation curve?

Answer 23

• anemia = less Hb but full saturation – results in lower maximum HbO2 content but still full saturation
• polycythemia = higher Hb at full saturation – so there is a higher Hb-O2 content

Question 24

how does carbon monoxide affect Hb-O2 binding?

Answer 24

• CO has a MUCH higher binding affinity for Hb than O2 does
• so sensitive that if PCO2 = 0.5mmHg, CO will be bound to 50% of Hb
• causes a shift to the left of the Hb-CO2 curve because CO will consume the binding sites

Question 25

why is CO2’s ability to bind to amino groups important?

Answer 25

• because CO2 has an affinity for binding with amino groups and Hb has amino groups
• it is favored for CO2 to interact more with Hb because of the presence of amino groups

Question 26

how is CO2 transported in the blood?

Answer 26

• bicarbonate!!! = the most important transporter of CO2
• to make bicarbonate, H2O + CO2 have to make carbonic acid – to do so is slow so you need carbonic anhydrase to speed it up
• carbonic acid isn’t very favorable for transport like bicarbonate, so there is small amounts of carbonic acid in blood and most is converted to bicarbonate

Question 27

how does CO2 get transported?

Answer 27

• it is formed in the tissue as a byproduct of metabolism
• diffuses from tissue into the plasma and dissolved CO2 forms carbamino, carbonic acid, or bicarbonate
• also can go from plasma to RBCs and dissolved CO2 forms carbaminos, carbonic acid, or bicarbonate
• formation of bicarbonate is favored when there are lots of hydrogen ions that are buffered by Hb
• the RBCs forms so much bicarbonate that the bicarbonate can move from the RBCs into the plasma
• Cl ions also move into RBCs to maintain neutral charge
• water moves into RBCs to maintain an osmotic equilibrium thus cells swell

Question 28

what is the total carbon dioxide content and in what forms is it found in the body?

Answer 28

• can be upwards of 50mL/dL
• mostly found in plasma bicarbonate
• can also be found as dissolved CO2, carbamino, red cell bicarbonate

Question 29

how does oxygen and carbon dioxide compare?

Answer 29