Blood Gas Transport

Question 1

What determines how much gas dissolves in a liquid?

Answer 1

Partial pressure and solubility of a gas.

Question 2

What is the equation linking concentration, partial pressure and solubility?

Answer 2

concentration ∝ partial pressure x solubility

Question 3

What would happen if a liquid were to be put in contact with a gas?

Answer 3

Some of the gas will dissolve
e.g O2 and CO2 will dissolve in plasma

Question 4

Why is haemoglobin critical to O2 transport? PART 1

Answer 4

• Oxygen has low solubility in plasma
• To dissolve the amount of O2 needed to supply tissues, a high alveolar PO2 would be required.

Question 5

Why is haemoglobin critical to O2 transport? PART 2

Answer 5

• Haemoglobin increases oxygen carrying capacity at gas exchange surfaces and then released at respiring tissues.

Question 6

How is the oxygen content of blood measured/defined?

Answer 6

• O2 partial pressure (PaO2) expressed as kPa
• Total O2 content (CaO2) expressed as ml of O2 per L of blood (ml/L)
• O2 saturation (SaO2 if measured directly in arterial blood, SpO2 if estimated by pulse oximetry) expressed as a percentage

Question 7

What does the oxygen-haemoglobin dissociation curve represent?

Answer 7

• Affinity of haemoglobin for oxygen.
• Relationship between O2 concentration, partial pressure and saturation.

Question 8

What is the sigmoidal shape of the dissociation curve produced by?

Answer 8

• cooperative binding (oxygen-haemoglobin affinity increases as more oxygen molecules bind, due to changes in the shape of the protein)
• saturation of oxygen sites

Question 9

Why is haemoglobin so effective at transporting O2 within the body? PART 1

Answer 9

• Structure of haemoglobin produces a high O2 affinity, therefore, a high level of Hb-O2 binding (and saturation) requires relatively low O2.
• Concentration of haem groups and haemoglobin contained in the RBCs enables a high carrying ability.

Question 10

Why is haemoglobin so effective at transporting O2 within the body? PART 2

Answer 10

• The oxygen-haemoglobin binding curve shifts to offload oxygen to demanding tissues.
• Haemoglobin O2 affinity changes depending on the local environment, enabling O2 delivery to be coupled on demand.

Question 11

How, and why, does the transport of CO2 differ to the transport of O2?

Answer 11

• CO2 has a higher H2O solubility than O2 does - therefore, a greater percentage of CO2 is transported simply dissolved in plasma.
• CO2 binds to haemoglobin at different sites than O2 does, and with a decreased affinity.
• CO2 also reacts with water to form carbonic acid - accounts for most CO2 transported.

Question 12

Venous blood carries more CO2 than arterial blood due to the Haldane Effect.
What is this effect?

Answer 12

• Oxygenation of blood in the lungs displaces carbon dioxide from haemoglobin, which increases the removal of carbon dioxide.
• Deoxyhaemoglobin has a higher affinity for CO2 than oxyHb does

Question 13

Describe, in detail, how carbon dioxide is brought into the RBC from the tissues (and kept there). PART 1

Answer 13

• CO2 is produced by respiring cells and dissolves in the plasma, then enters the RBCs.
• Conversion of CO2 + H2O to H2CO3 takes place within the RBCs, catalysed by carbonic anhydrase.
• Effective removal of CO2 by the previous step enables further CO2 to diffuse into the RBC, so that more enters into the plasma.

Question 14

Describe, in detail, how carbon dioxide is brought into the RBC from the tissues (and kept there). PART 2

Answer 14

• H2CO3 ionises into HCO3- and H+. The RBC membrane is impermeable to H+, therefore H+ cannot leave.
• Accumulation of H+ within the cell, and therefore a cessation of carbonic acid formation. This can be prevented by haemoglobin acting as a buffer and binding H+.
• Movement of O2 from the RBCs to the tissues increases the concentration of deoxyhaemoglobin, thus enabling more CO2 to be transported.

Question 15

Describe, in detail, how carbon dioxide is brought into the RBC from the tissues (and kept there). PART 3

Answer 15

• Increased HCO3- concentration creates a diffusion gradient for HCO3- to leave the cell. It is exchanged for Cl- to maintain electrical neutrality.

Question 16

Describe, in detail, how carbon dioxide is transferred to the lung alveoli from the RBCs. PART 1

Answer 16

• Low PACO2 creates a diffusion gradient for CO2 to diffuse out of the blood into the airspace.
• Increased PAO2 leads to oxygen-haemoglobin binding. Oxyhaemoglobin binds less H+ than deoxyhaemoglobin, increasing the concentration of free H+.

Question 17

Describe, in detail, how carbon dioxide is transferred to the lung alveoli from the RBCs. PART 2

Answer 17

• Increasing the concentration of free H+ leads to increased H2CO3 and, ultimately, CO2, which contributes to CO2 plasma saturation.
• Changing equilibrium of the carbonic acid reaction also leads to decreased HCO3- concentration, as it binds the free H+.
• Creates a diffusion gradient that allows HCO3- ions to enter the RBC in exchange for Cl-.

Question 18

What is cyanosis?

Answer 18

Purple discolouration of the skin and tissues when concentration of deoxyhaemoglobin becomes excessive.

Question 19

What are some clinical aspects of haemoglobin and oxygen transport?

Answer 19

• insufficient haemoglobin (anaemia)
• carbon monoxide poisoning

Question 20

How does carbon monoxide influence oxygen carrying capacity?

Answer 20

• Haemoglobin has high affinity for CO than it does for O2 and compete for the same binding site.
• CO poisoning decrease the oxygen-carrying capacity of the blood by decreasing the available haemoglobin-oxygen sites.
• The oxygen content decreases whilst saturation of the oxygen binding sites is normal.
• Reduced oxyhaemoglobin

Question 21

Why does the dissociation curve plateau over time?

Answer 21

Decreased availability of free O2 binding sites on the haemoglobin molecule

Question 22

Why does oxygen release increase in low partial pressure environments?

Answer 22

Haemoglobin readily releases large quantities of oxygen to respiring tissues.

Question 23

What can be inferred from leftward shifts of the dissociation curve?

Answer 23

• Higher Hb-O2 affinity
• Hb binds more O2 at a given PO2
• Less PaO2 is needed to get the same level of oxygen content/ saturation

Question 24

What can be inferred from rightward shifts of the dissociation curve?

Answer 24

• Lower Hb-O2 affinity
• Hb binds less O2 at a given PO2
• More PaO2 is needed to get the same level of oxygen content/saturation

Question 25

What is hypoxia?

Answer 25

Deficient supply of oxygen to tissues

Question 26

What is anaemia and what causes it?

Answer 26

Decrease in the number of red blood cells per unit volume of blood
- CAUSE: Decrease in RBC production

Question 27

What are the effects of anaemia?

Answer 27

• Reduction in the concentration of haemoglobin, total oxygen binding sites, and oxygen-carrying capacity.
• Affinity of haemoglobin is unchanged.
• Hb-O2 saturation and O2 partial pressure within the plasma will be normal
• Overall total O2 content of the blood will decrease, as will the overall concentration of both oxyhaemoglobin and deoxyhaemoglobin

Question 28

Why do pulse oximetry readings remain normal after CO poisoning?

Answer 28

• Technique cannot reliably differentiate between O2-Hb and CO-Hb

Question 29

What causes the curve to be shifted to the left during CO poisoning?

Answer 29

• Slight increase in O2-Hb affinity
• CO inhibits the production of 2,3-DPG

Question 30

What is central cyanosis?

Answer 30

Central cyanosis (discoloration of the core, mucous membranes and extremities) reflects inadequate oxygenation of blood within the lungs
- Due to hypoventilation, gas exchange defects or V/Q mismatch

Question 31

What is peripheral cyanosis?

Answer 31

Peripheral cyanosis (discoloration confined to the extremities) reflects inadequate oxygen supply to only these tissue
- Due to small vessel circulation problems

Question 32

Describe the role of erythropoietin in RBC production and oxygen transport

Answer 32

• Hormone which induces production of red blood cells within the bone marrow, secreted from the kidney.
• Increased EPO secretion occurs in chronic hypoxic respiratory disease, as well as individuals exposed to high altitude (due to the chronic hypoxia).

Question 33

How does the CVS respond to hypoxia?

Answer 33

• Hb saturation will decrease due to reduced PaO2,
• Cardiac output will increase via increased heart rate to increase overall oxygen transport

Question 34

Describe how the kidney maintains blood pH by maintaining [HCO3]

Answer 34

• Renal regulation of HCO3-
  e.g. regulating reabsorbtion/ excretion in glomerular filtrate

Question 35

Describe how the lungs maintain the blood pH by maintaining PaCO2

Answer 35

• Respiratory regulation of PaCO2
  e.g. regulating ventilation

Question 36

How is oxygen moved in the blood and in what proportions?

Answer 36

Dissolving in plasma (2%)
Binding to Hb (98%)

Question 37

What are the two causes of anaemia?

Answer 37

Iron deficiency
Haemorrhage (increased blood loss)

Question 38

Name some signs of CO poisoning

Answer 38

Headaches
Nausea
Dizziness
Loss of consciousness
Death

Question 39

What does increased oxyhaemoglobin mean for [CO2]?

Answer 39

[CO2] will decrease

Question 40

What is the difference between the haldane and the Bohr effect?

Answer 40

Haldane- concerns impact of O2 on CO2 transport
Bohr- concerns impact of CO2 on O2 transport

Question 41

How does the Bohr effect work?

Answer 41

Binding of CO2 to Hb induces a different structural change to Hb, which reduces Hb affinity for O2

Question 42

What can be diagnosed and interpreted from analysis of arterial blood gases and pH?

Answer 42

Signs of respiratory and metabolic distress

Question 43

What molecule transport is important in acid-base balance?

Answer 43

CO2

Question 44

What are the different situations that cause the Oxygen-Haemoglobin Dissociation curve to shift to the left?

Answer 44

• Decrease in CO2
• Increase in pH (alkalosis)
• Decrease in 2,3-DPG
• Decrease in temperature

Question 45

What are the different situations that cause the Oxygen-Haemoglobin Dissociation curve to shift to the right?

Answer 45

• Increase in CO2
• Decrease in pH (acidosis)
• Increase in 2,3-DPG
• Increase in temperature

Question 46

How are the Hb-O2 affinities altered in the lungs to suit the local environment?

Answer 46

• At the lungs the blood needs to take in oxygen.
• High levels of PO2
• Low levels of PCO2 - high pH
• Curve shifts to the left.
• Hb-O2 affinity increases

Question 47

How are the Hb-O2 affinities altered in resting tissues to suit the local environment?

Answer 47

• Low PO2
• Lower demand for oxygen
• Medium/normal levels of PCO2 (so a normal pH).
• Curve hasn’t shifted and so affinity is not affected.
• Slight decrease in O2 saturation as Hb gives off O2 to meet the smaller demands.

Question 48

How are the Hb-O2 affinities altered in hard working tissues to suit the local environment? PART 1

Answer 48

• Major decrease in PO2
• Anaerobic respiration takes place
• Produces lactic acid (decreasing pH), CO2 and 2,3-DPG.

Question 49

How are the Hb-O2 affinities altered in hard working tissues to suit the local environment? PART 2

Answer 49

• High oxygen demand
• Curve shifts to the right due to the conditions
• Lower Hb-O2 affinity and so a lower saturation of O2 as more oxygen is given off to tissue from the Hb

Question 50

Why is cyanosis harder to spot in patients with low RBC density?

Answer 50

• Low concentration of deoxyhaemoglobin
• Discolouration will be less visible

Question 51

How does the Haldane effect cause acidaemia in tissue?

Answer 51

• Upon binding to oxygen the CO2 will be dissociated from the Hb
• Causes chronic hypercapnia as the CO2 will build up in the blood
• CO2 builds up in the tissues (as they are not taken up) causing acidosis leading to acidaemia

Question 52

How does an increase in CO2 accumulation cause acidosis?

Answer 52

CO2+ H20 <=> H2CO3 <=> H+ + HCO3-
- If CO2 were to accumulate (e.g. hypoventilation) more H2CO3 would be formed.
- An increase in H2CO3 would mean an increased production of carbonic acid.
- This means concentration of H+ increases so pH also decrease
- This decrease in pH causes acidosis

Question 53

How does excessive removal of CO2 cause alkalosis?

Answer 53

CO2+ H20 <=> H2CO3 <=> H+ + HCO3-
- If excess removal of CO2 took place (e.g. hyperventilation) H2CO3 would be converted into CO2 to replace the CO2 that is lost.
- This means more H2CO3 would be formed from the H+ ions to replace the lost H2CO3.
- So less H+ ions will be found in the blood which means pH increases leading to alkalosis

Question 54

Why is it advantageous for oxygen release to occur at low pHs, high CO2 levels etc.?

Answer 54

These are the conditions when there will be greatest demand for oxygen

Question 55

One consequence of the Haldane effect is that it can be dangerous to start supplemental O2 therapy too quickly in patients with severe COPD. Suggest why. PART 1

Answer 55

• COPD patients chronically hypoventilate their lungs, therefore CO2 levels rise within the body.
• However the blood of such patients has greater CO2 capacity due to the low levels of O2 and the Haldane effect.

Question 56

One consequence of the Haldane effect is that it can be dangerous to start supplemental O2 therapy too quickly in patients with severe COPD. Suggest why. PART 2

Answer 56

• When oxygen levels suddenly increase (e.g. with the onset of supplemental O2 therapy), the CO2 is displaced from the blood as it can carry less CO2 bound to Hb and as HCO3-. This leads to sudden very high levels of CO2 within the body, potentially
  leading to a dangerous acidaemia.