Haemoglobin and gas transport 1,2/

Question 1

how much O2 is dissolved per litre of plasma?

Answer 1

3mL

Question 2

why use haemoglobin? what is the blood’s O2 carrying capacity because of haemoglobin?

Answer 2

increases blood’s carrying capacity to 200mL/L

Question 3

what proportion of CO2 is dissolved per litre of plasma?

Answer 3

the bulk of it

Question 4

what phase do gases travel in the blood in?

Answer 4

they are dissolved in liquid, were they gaseous they would crete fatal air embolism

Question 5

what is each haemoglobin chain attached to?

Answer 5

iron heme group

Question 6

what does O2 bind to in the haemoglobin?

Answer 6

1 heme binds to oxygen, so 4 oxygens can be fixed by haemoglobin

Question 7

what is cooperative binding, how is it relevant to haemoglobin?

Answer 7

cooperativity, because as O2 starts to bind, the conformation changes and makes it easier for more O2 to arrive, also when O2 leaves, conformation changes and makes it easier for th other O2 to leave (change in conformation changes affinity)

Question 8

how many alpha and beta chains in HbA?

Answer 8

2 alpha and 2 beta

Question 9

what is the lifespan of a red blood cells?

Answer 9

120 days

Question 10

how oxygenated is deoxygenated blood?

Answer 10

75%

Question 11

why is arterial partial pressure of O2 not the same as arterial O2 content?

Answer 11

because arterial partial pressure accounts for only the O2 dissolved in the blood, and not the O2 attached to haemoglobin

Question 12

what is the relation between the partial pressure of a gas in solution and the partial pressure in gaseous phase (before it is driven into solution)

Answer 12

they are equal, i.e. the partial pressure at the alveoli is the same as the partial pressure inside the blood

Question 13

what is O2’s solubility in water?

Answer 13

0,03mL/L/mmHg

Question 14

how much plasma do we have per litre?

Answer 14

3mL/L plasma

Question 15

what is the partial pressure driving O2 into the liquid phase in plasma (ie the partial pressure at the alveoli, also the partial pressure in solution)

Answer 15

3/0,03=100, 100 mmHg, known as the oxygen tension

Question 16

what is the O2 demand of resting tissues?

Answer 16

250mL/min

Question 17

what is the cardiac output?

Answer 17

5L/min

Question 18

what is the rate of O2 delivery to tissue, counting only the O2 diluted in the plasma?

Answer 18

3mL/L x 5L/min = 15mL/min

Question 19

what is the rate of O2 delivery to tissue, counting only the O2 carried by the hemes?

Answer 19

200mL/L x 5L/min = 1000mL/min

Question 20

what percentage of arterial O2 is extracted by peripheral tissues at rest?

Answer 20

250mL/min : 1000mL/min

Question 21

what is the percentage of O2 bound to haemoglobin?

Answer 21

1-(15/1000) = 98,5%

Question 22

what percentage of Hb in RBC is in the form HbA? what does this form consist of? what makes up the rest of that percentage?

Answer 22

92%, 2 alpha and 2 beta chains. The remaining 8% is HbA2, HbF and glycosylated Hb

Question 23

what does the HbA2 form consist of?

Answer 23

2 alpha and 2 delta

Question 24

what does the HbF form consist of?

Answer 24

2 alpha and 2 gamma

Question 25

which forms of Hb are glycosylated Hb?

Answer 25

HbA1a, HbA1b, HbA1c

Question 26

what is the major determinant of the degree to which haemoglobin is saturated with oxygen?

Answer 26

the partial pressure of oxygen in arterial blood

Question 27

where does Hb get its O2 from? the alveoli or the arterial plasma?

Answer 27

the plasma, that way there is a permanent partial pressure gradient between the alveoli and the arterial plasma, which means the arterial plasma is constantly filled up with O2 (to maintain 100 mmHg)

Question 28

how long does it take for the Hb to become saturated?

Answer 28

0,25s contact time

Question 29

what is the total contact time between alveoli and plasma?

Answer 29

about 0,75s

Question 30

why is the partial pressure of O2 fundamental in binding to Hb?

Answer 30

it determines how much O2 binds to Hb

Question 31

how saturated is Hb at the normal systemic arterial PO2 of 100mmHg?

Answer 31

almost saturated

Question 32

how saturated is Hb at the systemic arterial PO2 of 60mmHg? what does this permit?

Answer 32

90% saturated, permits high uptake of O2 even when alveolar PO2 is moderately reduced

Question 33

how saturated is Hb at the normal venous PO2?

Answer 33

75% saturated

Question 34

How can Hb be saturated at any other level than 0, 25, 50, 75, 100? (because it only has 4 hemes)

Answer 34

the saturation number looks at all the Hb, a level of near saturation might correspond to most Hb having 4 O2 molecules, and a couple having only 3

Question 35

rank myoglobin, foetal haemoglobin, normal haemoglobin in terms of affinity for O2, from less to most

Answer 35

normal haemoglobin, foetal haemoglobin, myoglobin

Question 36

why has foetal Hb got more affinity for O2 than normal Hb?

Answer 36

because it draws its O2 from the mother’s blood, which has poorer O2 levels (as some O2 has already been taken for the mother’s systemic circulation)

Question 37

is the relation between PO2 and saturation of Hb linear? why?

Answer 37

no (i.e. if PO2 decreases by 72%, there is only a 50% decrease in Hb O2 saturation), because of usage of more than 25% of the oxygen available (which is something it does under normal PO2) thanks to variations in Hb affinity

Question 38

what is anaemia?

Answer 38

any condition where the oxygen carrying capacity of the blood is compromised

Question 39

what happens to PaO2 in anaemia?

Answer 39

it would be the same because PaO2 is independent from any oxygen carrying elements

Question 40

what happens to total blood O2 content in anaemia?

Answer 40

decreases

Question 41

what might cause anaemia?

Answer 41

iron deficiency, haemorrhage, vitB12 deficiency

Question 42

can you have a low PaO2 and normal blood O2 content?

Answer 42

no, PaO2 determines how saturated Hb becomes (Hb gets its O2 from the blood, where O2 pressure is determined by PaO2)

Question 43

how saturated is Hb in an anaemic patient? (assuming normal PaO2)

Answer 43

100%, even though they have less Hb

Question 44

how saturated is Hb in a patient with iron deficiency?

Answer 44

not 100% because iron deficiency affects the number of available hemes

Question 45

what 4 factors make Hb saturation vary?

Answer 45

pH, PCO2, temperature and concentration of DPG

Question 46

in certain conditions, the blood can “tap in” which O2 “reserve”?

Answer 46

O2 which accounts for 75% saturation of Hb in veinous blood (the rest of the 1000mL/min not used by tissues)

Question 47

how do you call a shift to the right of an O2-Hb dissociation curve?

Answer 47

Bohr effect

Question 48

how does the affinity of CO and O2 to Hb compare?

Answer 48

CO has affinity 250 times higher (binds easily, dissociates very slowly)

Question 49

what consequences does this have?

Answer 49

CO displaces O2 and replaces it on Hb

Question 50

why does this not cause any ventilation issue?

Answer 50

no higher levels of CO2, therefore no increase in ventilation

Question 51

what is hypoxia? how many different types are there?

Answer 51

inadequate supply of oxygen to tissues, 5 types

Question 52

what is hypoxic hypoxia? how common is it?

Answer 52

reduction in O2 diffusion at lungs because of tissue pathology or breathing in air with lower PO2, it is the most common type

Question 53

what is anaemic hypoxia?

Answer 53

reduction in O2 carrying capacity of blood due to anaemia (RBC loss/ iron deficiency)

Question 54

what is ischaemic (stagnant) hypoxia?

Answer 54

heart disease results in inefficient pumping of blood to lungs/ around the body

Question 55

what is histotoxic hypoxia?

Answer 55

poisoning prevents cells utilising oxygen delivered to them (e.g.: carbon monoxide/cyanide)

Question 56

what is metabolic hypoxia?

Answer 56

oxygen delivery to the tissues does not meet increased oxygen demand by cells

Question 57

how would the body compensate for respiratory alkalosis?

Answer 57

hypoventilation

Question 58

how would the body compensate for respiratory alkalosis?

Answer 58

hypoventilation

Question 59

who would alveolar PO2 compare with arterial PO2 if oxygen was transported in blood without Hb?

Answer 59

alveolar PO2 = arterial PO2

Question 60

what decreases affinity of haemoglobin for oxygen?

Answer 60

decrease in pH, increase in PCO2, increases in temperature

Question 61

does this decrease in affinity exist locally?

Answer 61

yes, in actively metabolising tissues to facilitate the dissociation of oxygen from Hb

Question 62

what increases affinity of Hb for O2?

Answer 62

rise in pH, fall in PCO2, fall in temperature

Question 63

what consequences does this increase in affinity have?

Answer 63

makes oxygen unloading more difficult but aids collection of oxygen in the pulmonary circulation

Question 64

affinity of Hb for O2 increases/decreases by binding to 2,3BPG?

Answer 64

decreases

Question 65

what is 2,3BPG synthesised by?

Answer 65

erythrocytes

Question 66

under what conditions would 2,3BPG levels rise?

Answer 66

situations associated with inadequate oxygen supply (heart or lung disease, living at high altitude)

Question 67

what does the release of 2,3BPG do?

Answer 67

helps maintain oxygen release in the tissues

Question 68

from what PCO can CO cause progressive carboxyhemoglobin formation?

Answer 68

0,4 mmHg

Question 69

what are the symptoms of CO poisoning?

Answer 69

hypoxia, anaemia, nausea, headaches, cherry red skin, mucous membranes, potential brain damage, death

Question 70

how does CO2 change ECF pH?

Answer 70

CO2 + H2O H2CO3 HCO3 + H+, and pH decreases if (H+) increases

Question 71

how does the respiratory system maintain pH?

Answer 71

all the CO2 produced is eliminated in expired air

Question 72

what happens if this balance is disrupted, and the body undergoes hypoventilation?

Answer 72

hypoventilation causes CO2 retention, leads to increased (H+) bringing about respiratory acidosis

Question 73

what happens if this balance is disrupted, and the body undergoes hyperventilation?

Answer 73

hyperventilation blows off more CO2, leads to decreased (H+) bringing about respiratory alkalosis