Blood gas transport Flashcards

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1
Q

How does oxygen get from the atmosphere to the cells?

A

O2 inhaled from atmosphere into alveoli within lungs.

O2 diffuses from alveoli into blood within pulmonary capillaries.

O2 transported in blood, predominantly bound to haemoglobin.

O2 diffuses into cells/tissues for use in aerobic respiration.

CO2 diffuses from respiring tissues to blood – exchanged at lungs.

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2
Q

What is the primary form gases are found in the blood?

A

→ gases carried in the blood first dissolve in the plasma.

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3
Q

What is plasma?

A

→ Aqueous portion of blood

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4
Q

How does O2 from the lungs bind to Hb?

A

→ O2 exchange at the lungs
→ O2 dissolved in plasma
→ O2 bound to Hb

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5
Q

How does O2 go into the tissues from being bound to Hb?

A

→ O2 bound to Hb
→ O2 dissolved in plasma
→ O2 diffuses into tissues

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6
Q

How much O2 is in Hb?

A

→ 98%

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7
Q

How much O2 is dissolved in plasma?

A

→ 2%

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8
Q

How does CO2 go from the tissues to being bound to Hb?

A

→ CO2 produced by tissues
→ CO2 dissolved in plasma ( PaCO2)
→ CO2 bound to Hb or transported as HCO3-

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9
Q

How does CO2 get to the lungs from Hb or HCO3-?

A

→ CO2 bound to Hb or being transported as HCO3-
→ CO2 dissolved in plasma
→ CO2 exchange at the lung

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10
Q

How much CO2 exists as HCO3-?

A

→ 70%

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11
Q

How much CO2 exists as HbCO2?

A

→ 23%

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12
Q

How much CO2 exists in the dissolved form?

A

→ 7%

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13
Q

Why is Hb essential to O2 transport?

A

→Oxygen has low solubility in plasma

→ In order to dissolve the amount of O2 needed to supply tissues, an impossibly high alveolar PO2 would be required.

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14
Q

What does Hb enable?

A

→It enables O2 to be concentrated within blood (↑ carrying capacity)

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15
Q

What is PaO2?

A

→The partial pressure of O2 within a gas phase (at a gas-liquid interface) that would yield this much O2 in the plasma at equilibrium

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16
Q

What is CaO2 and how is it expressed?

A

→What volume of O2 is being carried in each litre of blood, including O2 dissolved in the plasma and O2 bound to Hb
→expressed as mL of O2 per L of blood (ml/L)

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17
Q

What is SaO2?

A

→What % of total available haemoglobin binding sites are occupied by oxygen

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18
Q

How is SaO2 and SpO2 measured and how are they expressed?

A

→SaO2 = measured directly in arterial blood
→SpO2 = estimated by pulse oximetry
→ expressed as %

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19
Q

What is the initial steep gradient of an ODC (Oxygen dissociation curve)?

A

→ Co-operative binding of O2 to Hb

20
Q

What is co-operative binding?

A

→ Once the first molecule of O2 binds to Hb it gets easier for subsequent molecules of O2 to bind

21
Q

Why does the ODC plateau?

A

→ Saturation of O2 binding sites

22
Q

Why is Hb so effective at transporting O2 within the body?

A

→ The structure of Hb produces a high O2 affinity so a high level of O2 binding requires low PO2.

23
Q

What enables high carrying capacity of Hb?

A

→ The concentration of heme groups + Hb contained in RBCs

24
Q

How does the ODC change depending on the environment?

A

→The curve shifts to offload oxygen to demanding tissues

25
Q

How does the curve shift if the pH is low and what is this called?

A
→curve shifts right
→ more CO2 
→ Hb gives up O2 more readily 
→ more 2,3 DPG
→ higher temperature 
→Bohr Shift
26
Q

How does the curve shift if the pH is high?

A
→curve shifts left
→ CO2 decreases
→ less 2,3 DPG
→Decreased temperature
→ Hb has a higher affinity for O2
27
Q

What is O2 demand like in the lungs?

A
→ High PO2
→ Low PCO2
→ High pH
→ Hb has high O2 saturation
→ LOW DEMAND = Hb Has high O2 affinity and less dissociation
→ Left shifted curve
28
Q

What is O2 demand like in resting tissues?

A

→ Low PO2
→ Hb has a low O2 saturation
→ More O2 moves from Hb to tissue
→ MODERATE DEMAND = Hb has lower O2 affinity and more dissociation

29
Q

What is O2 demand like in working tissues?

A

→ Low PO2
→ Anaerobic respiration + hypoxia produces H+, CO2 and 2,3 DPG
→ Increased O2 demand leads to a high CO2, low pH, high 2,3 DPG
→ More O2 moves from Hb to tissue
→ VERY HIGH DEMAND = Hb has a much lower O2 affinity and a lot more dissociation

30
Q

What does myoglobin do?

A

→ Acts as an O2 reservoir within muscle tissue and only releases O2 at a low PO2

31
Q

How does O2 transfer occur in fetal Hb?

A

→Where fetal + maternal Hb come into contact in the placenta
→ O2 is transferred to the high affinity fetal Hb
→effectively ‘steals’ O2 from maternal Hb

32
Q

What is cyanosis?

A

→purple discoloration of the tissue or skin that occurs when deoxyhaemoglobin becomes excessive

33
Q

Describe central cyanosis

A

→Bluish discoloration of core, mucous membranes and extremities
→ Inadequate oxygenation of blood
→ Hypoventilation or V/Q mismatch

34
Q

Describe peripheral cyanosis

A

→ Bluish discoloration confined to extremities
→ Inadequate O2 supply to extremities
→small vessel circulation issues

35
Q

What are three causes of anaemia?

A

→ Insufficient Hb
→ Iron deficiency
→ Haemorrhage

36
Q

What is the main consequence of anaemia?

A

→ Hypoxia can occur despite adequate ventilation + perfusion

→ blood is not able to carry sufficient O2 to meet tissue demands due to a lack of Hb

37
Q

How does anaemia affect the ODC curve?

A

→ Curve is much lower than normal

38
Q

Why is a greater % of CO2 transported in the plasma?

A

→ CO2 has a higher solubility than O2

39
Q

Why is there a smaller % of CO2 transported bound to Hb?

A

→ CO2 binds to Hb at different sites than O2

→ Forms carbamino Hb

40
Q

How is the majority of CO2 transported?

A

→ Reacts with water to form carbonic acid which accounts for 70% of CO2 transported

41
Q

What is the Haldane effect?

A

→ Deoxygenated blood carries more CO2

42
Q

How does CO2 saturation differ in venous and arterial blood?

A

→ Venous blood carries more CO2 than arterial blood

→ Arterial blood Hb is saturated with CO2 at a much lower PCO2 than venous blood

43
Q

What are the ways CO2 is transported in the blood?

A
→ CO2 is produced in tissues
→ Dissolved in plasma
→ Dissolved in RBCs
( forms H2CO3 which dissociates to HCO3- and H+, the H+ can be bound to Hb) 
→ CO2 is bound to Hb
44
Q

What happens to the CO2 when oxygen is bound to Hb?

A
→ The O2 'displaces' the CO2 from Hb
→ CO2 goes back into the RBCs
→ CO2 goes back into the plasma 
→ Removed by the lungs 
→ H+ bound to Hb joins with HCO3- and forms carbonic acid
45
Q

Describe the process of CO2 exchange between RBCs and respiring tissues

A

1) CO2 is produced by respiring cells which dissolves in the plasma ( 7%)
2) Conversion of CO2 + H2O to H2CO3 takes place within the RBCs, catalysed by carbonic anhydrase.
3) The effective removal of CO2 by step (2) enables further CO2 to diffuse into the RBC, so that more can enter into the plasma.

4) H2CO3 ionises into HCO3- and H+.
The RBC membrane is impermeable to H+, therefore H+ cannot leave.

5) There is an accumulation of H+ within the cell, and therefore a cessation of step (2).
This can be prevented by haemoglobin acting as a buffer and binding H+.
Also, the movement of O2 from the RBCs to the tissues increases the concentration of deoxyhaemoglobin, thus enabling more CO2 to be transported.

6) The increased HCO3- concentration creates a diffusion gradient for HCO3- to leave the cell. It is exchanged for Cl- to maintain electrical neutrality.

46
Q

Describe the process of exchange of CO2 from the lungs

A

1) A low PACO2 creates a diffusion gradient for CO2 to diffuse out of the blood into the airspace.
2) An increased PAO2 leads to oxygen-haemoglobin binding. Oxyhaemoglobin binds less H+ than deoxyhaemoglobin, increasing the concentration of free H+.

3) Increasing the concentration of free H+ leads to
increased H2CO3 and, ultimately, CO2, which contributes to CO2 plasma saturation.

4) The changing equilibrium of the carbonic acid reaction also leads to decreased HCO3- concentration, as it binds the free H+.
This creates a diffusion gradient that allows HCO3- ions to enter the RBC in exchange for Cl-.