Control of Acid/Base

Question 1

What is the normal range of plasma pH?

Answer 1

7.38-7.46

Question 2

What is the normal H+ concentration of the plasma?

Answer 2

37-43nmol/L

Question 3

When are the effects of acidaemia severe?

Answer 3

Below pH 7.1

Question 4

When are the effects of acidaemia life threatening?

Answer 4

Below pH 7.0

Question 5

What are the effects of acidaemia?

Answer 5

• Reduced enzyme function
• Reduced glycolysis
• Reduced cardiac and skeletal muscle contractility
• Reduced hepatic function
• Increased plasma potassium

Question 6

What is the effect of alkalaemia on calcium salts?

Answer 6

Reduces their solubility

Question 7

What is the result of the reduced solubility of calcium salts in alkalaemia?

Answer 7

Means that free Ca2+ leaves the ECF

Question 8

How does free Ca2+ leave the ECF?

Answer 8

Binds to bone and protein

Question 9

What is the result of free Ca2+ leaving the ECF in alkalaemia?

Answer 9

Results in hypocalcaemia

Question 10

What is the effect of hypocalcaemia?

Answer 10

Increases the excitability of nerves

Question 11

What happens at pH > 7.45?

Answer 11

Parasthesia

Tetany

Question 12

What is tetany?

Answer 12

Uncontrolled muscle contractions

Question 13

What happens at pH > 7.55?

Answer 13

45% mortality

Question 14

What happens at pH > 7.65?

Answer 14

80% mortality

Question 15

Describe the H+ ion concentration of the ECF?

Answer 15

It is very low

Question 16

What is the result of the H+ concentration of the ECF being very low?

Answer 16

The addition of small amounts of acid changes the concentration and therefore the pH dramatically

Question 17

What prevents the addition of small amounts of acid to the ECF changing the pH dramatically?

Answer 17

The carbon dioxide/hydrogen carbonate system acts as an important buffer for the H⁺ ions

Question 18

What reaction occurs in the carbon dioxide/hydrogen carbonate system?

Answer 18

H2O+CO2 H2CO3 (carbonic acid) H+ + HCO3-

H+ reacts with OH to produce water

Question 19

What is the extent to which the reversible reaction proceeds in the carbon dioxide/hydrogen carbonate system determined by?

Answer 19

The ratio of pCO2 of plasma to [HCO3-]

Question 20

What is the pCO2 of plasma controlled by?

Answer 20

Lungs

Question 21

What is HCO3- created by?

Answer 21

Largely RBC

Question 22

What is the concentration of plasma HCO3- controlled by?

Answer 22

Kidneys

Question 23

What is the normal [HCO3-]:pCO2 ratio?

Answer 23

20:1

Question 24

What is the result of anything that alters the [HCO3-]:pCO2 ratio?

Answer 24

It also alters the pH

Question 25

What happens in respiratory alkalaemia?

Answer 25

As hyperventilation leads to hypocapnia (fall in pCO2), the ratio is altered and pH will rise. There is more than 20x the amount of HCO3- than CO2, so relatively more H+ ions are buffered, causing the pH increase

Question 26

What pH is considered respiratory alkalaemia?

Answer 26

> 7.45

Question 27

Why must is be respiratory alkalaemia if breathing quickly?

Answer 27

If lungs were fine, breathing would be slowed to raise pCO2

Question 28

What happens in respiratory acidaemia?

Answer 28

Hypoventilation leads to hypocapnia. The ratio is altered and pH will fall. There is less than 20x the amount of HCO3- than CO2, so relatively less H+ ions are buffered, causing the pH to decrease

Question 29

What pH is considered respiratory acidaemia?

Answer 29

<7.35

Question 30

Why must it be respiratory acidaemia if breathing slowly?

Answer 30

Because if lungs were fine, breathing would be sped up to lower pCO2

Question 31

What can compensate respiratory alkalosis or acidosis?

Answer 31

Changes in [HCO3-] controlled by the kidney

Question 32

Why can respiratory acidosis or alkalosis be compensated for by the kidney?

Answer 32

Because the pH is controlled by the ratio, and not absolute values.

Question 33

How does the kidney control [HCO3-]?

Answer 33

Variable renal excretion/production

Question 34

What does the kidney do if pCO2 rises?

Answer 34

[HCO3-] rises proportionally to restore pH

Question 35

What does a rise in [HCO3-] caused by the kidney compensate for?

Answer 35

Respiratory acidosis

Question 36

What does the kidney do if pCO2 falls?

Answer 36

[HCO3-] falls proportionally to restore pH

Question 37

What does a fall in [HCO3-] caused by the kidney compensate for?

Answer 37

Respiratory alkalosis

Question 38

What metabolic processes produce H+ ions?

Answer 38

Metabolism of amino acids or the production of ketones

Question 39

What happens to metabolically produced H+ ions?

Answer 39

They react with HCO3- to produce CO2 in venous blood

Question 40

What happens to the CO2 produced by the reaction of metabolically produced H+ ions?

Answer 40

It is breathed out through the lungs

Question 41

What is the result of the breathing out of the CO2 production by the reaction of metabolically produced H+ ions?

Answer 41

It gives a directly proportional (1mmol acid:1mmol HCO3-) reduction in arterial HCO3-

Question 42

What is the result of the directly proportional reduction in arterial HCO3- caused by metabolically produced H+?

Answer 42

It alters the [HCO3-]:pCO2 ratio, meaning that less than 20x the amount of HCO3- than CO2. Relatively less H+ ions are buffered, causing a pH decrease

Question 43

What is it called when metabolically produced H+ ions cause a pH decrease?

Answer 43

Metabolic acidosis

Question 44

What pH is considered metabolic acidosis?

Answer 44

<7.35

Question 45

What can compensate for metabolic acidosis or alkalosis?

Answer 45

The lungs

Question 46

Why can the lungs compensate for metabolic acidosis or alkalosis?

Answer 46

As pH depends on the ratio of [HCO3-]:pCO2, so the lungs can change pCO2.

Question 47

What do the lungs normally do regarding CO2?

Answer 47

Keep it within tight limits

Question 48

How is CO2 normally kept within tight limits by the lungs?

Answer 48

By central chemoreceptors

Question 49

How do changes in plasma pH drive changes in pCO@?

Answer 49

Via the peripheral chemoreceptors

Question 50

What happens if [HCO3-] falls?

Answer 50

pCO2 is lowered proportionally by increasing ventilation

Question 51

What does the increase in ventilation due to a fall in [HCO3-] compensate for?

Answer 51

Metabolic acidosis

Question 52

What happens if [HCO3-] rises?

Answer 52

pCO2 may be slightly raised by reducing ventilation

Question 53

What does the reduction in ventilation due to a increase in [HCO3-] compensate for?

Answer 53

Metabolic alkalosis, although only partially

Question 54

What happens to pH in respiratory acidosis?

Answer 54

Decreased

Question 55

What happens to pCO2 in respiratory acidosis?

Answer 55

Increased

Question 56

Why is pCO2 increased in respiratory acidosis?

Answer 56

Hypoventilation

Question 57

What happens to [HCO3-] in respiratory acidosis?

Answer 57

Unchanged

Question 58

What happens to pO² in respiratory acidosis?

Answer 58

Decreased

Question 59

What happens to pH in compensated respiratory acidosis?

Answer 59

pH decreased or normal

Question 60

What happens to pCO2 in compensated respiratory acidosis?

Answer 60

Increased

Question 61

What happens to [HCO3-] in compensated respiratory acidosis?

Answer 61

Increased

Question 62

What happens to pO2 in compensated respiratory acidosis?

Answer 62

Decreased

Question 63

What is happening in compensated respiratory acidosis?

Answer 63

Kidneys have increased [HCO3-]. This causes increases in buffering of H+ ions caused by increased pCO2.

Question 64

What happens to pH in respiratory alkalosis?

Answer 64

Increase

Question 65

What happens to pCO2 in respiratory alkalosis?

Answer 65

Decrease

Question 66

Why does pCO2 decrease in respiratory alkalosis?

Answer 66

Hyperventilation

Question 67

What happens to [HCO3-] in respiratory alkalosis?

Answer 67

Unchanged

Question 68

What happens to pO2 in respiratory alkalosis?

Answer 68

Normal or increased

Question 69

What happens to pH in compensated respiratory alkalosis?

Answer 69

Increased or normal

Question 70

What happens to pCO2 in compensated respiratory alkalosis?

Answer 70

Reduced

Question 71

What happens to [HCO3-] in compensated respiratory alkalosis?

Answer 71

Decreased

Question 72

What happens to pO2 in compensated respiratory alkalosis?

Answer 72

Increased

Question 73

What is happening in compensated respiratory alkalosis?

Answer 73

Kidneys have decreased [HCO3-], decreasing buffering of H+ ions

Question 74

What happens to pH in metabolic acidosis?

Answer 74

Decreased

Question 75

What happens to pCO2 in metabolic acidosis?

Answer 75

Unchanged

Question 76

What happens to [HCO3-] in metabolic acidosis?

Answer 76

Decreased

Question 77

What happens to pO2 in metabolic acidosis?

Answer 77

Unchanged

Question 78

What happens to the anion gap in metabolic acidosis?

Answer 78

Increased

Question 79

What is happening in metabolic acidosis?

Answer 79

Decreased [HCO3-] means less buffering of H+ ions

Question 80

Why is here an increase in the amnion gap in metabolic acidosis?

Answer 80

Increase in unmeasured anions because anions associated with increase in H+ has taken HCO3- places

Question 81

What happens to pH in compensated metabolic acidosis?

Answer 81

Decreased or normal

Question 82

What happens to pCO2 in compensated metabolic acidosis?

Answer 82

Decreased

Question 83

What happens to [HCO3-] in compensated metabolic acidosis?

Answer 83

Decreased

Question 84

What happens to pO2 in compensated metabolic acidosis?

Answer 84

Increased or unchanged

Question 85

What happens to the anion gap in compensated metabolic acidosis?

Answer 85

Increased

Question 86

What is happening in compensated metabolic acidosis?

Answer 86

Increased respiratory rate is leading to hypocapnia and therefore raised pH

Question 87

What happens to the pH in metabolic alkalosis?

Answer 87

Increased

Question 88

What happens to pCO2 in metabolic alkalosis?

Answer 88

Unchanged

Question 89

What happens to [HCO3-] in metabolic alkalosis?

Answer 89

Increased

Question 90

What happens to pO2 in metabolic alkalosis?

Answer 90

Unchanged

Question 91

What is happening in metabolic alkalosis?

Answer 91

Increased [HCO3-] means increased buffering of H+

Question 92

What happens to pH in compensated metabolic alkalosis?

Answer 92

It increases or is normal

Question 93

What happens to pCO2 in compensated metabolic alkalosis?

Answer 93

Increase

Question 94

What happens to [HCO3-] in compensated metabolic alkalosis?

Answer 94

Increased

Question 95

What happens to pO2 in compensated metabolic alkalosis?

Answer 95

Decreased or unchanged

Question 96

What is happening in compensated metabolic alkalosis?

Answer 96

Decreased respiratory rate, so hypercapnia, so decreased pH

Question 97

How is HCO3- reabsorbed in the PCT?

Answer 97

• 3Na/2K-ATPase sets up Na+ concentration gradient in PCT cells
• H+ ions are pumped out of the apical membrane up their concentration gradient in exchange for the inward movement of Na down its concentration gradient
• H+ reacts with filtered HCO3-, producing CO2, which enters the cell and reacts with water to produce H+ ions
• H+ is quickly exported, recreating HCO3-, which crosses the basolateral membrane to enter the plasma

Question 98

What % of filtered HCO3- is reabsorbed in the PCT?

Answer 98

80-90%

Question 99

Other than the PCT, where else is HCO3- reabsorbed?

Answer 99

In the TAL of the loop of Henle

Question 100

What % of filtered HCO3- is reabsorbed in the loop of Henle?

Answer 100

Up to 15%

Question 101

How does the mechanism of HCO3- reabsorption in the loop of Henle compare to that in the PCT?

Answer 101

It is similar

Question 102

What has happened to HCO3- by the DCT?

Answer 102

Most/all of the filtered HCO3- has been recovered

Question 103

Is the Na+ gradient sufficient to drive H+ secretion in the DCT?

Answer 103

No

Question 104

What is the result of the Na+ gradient being insufficient to drive H+ reabsorption in the DCT?

Answer 104

H+ is pumped across the apical membrane by H+-ATPase

Question 105

What are the H+-ATPase pumps found in the DCT similar to?

Answer 105

Those found in the stomach

Question 106

What happens, regarding K+, when tubular cells export H+?

Answer 106

K+ is absorbed into the blood

Question 107

What is the result of K+ be absorbed into the blood when tubular cells export H+ in tubule lumen?

Answer 107

If you export a lot of H+, you will also absorb a lot of K+

Question 108

What is the result of the relationship between H+ exportation and K+ absorption?

Answer 108

Blood pH is linked to [K+]

Question 109

What is the minimum pH of urine?

Answer 109

4.5

Question 110

Is HCO3- found in urine?

Answer 110

No

Question 111

What is the result of HCO3- not being found in urine?

Answer 111

H+ is buffered by phosphate

Question 112

What kind of acid is phosphate?

Answer 112

Titratable

Question 113

What is meant by phosphate being a titratable acid?

Answer 113

It can freely gain H+ ions in an acid/base reaction

Question 114

What happens to the H+ in urine not buffered by phosphate?

Answer 114

It is attached to ammonia as ammonium

Question 115

What is metabolic acidosis associated with?

Answer 115

Hyperkalaemia

Question 116

Why is metabolic acidosis associated with hyperkalaemia?

Answer 116

As [K+] rises, the kidneys ability to reabsorb and create [HCO3-] is reduced. Hyperkalamia makes the intracellular pH alkaline, favouring HCO3- excretion

Question 117

What is metabolic alkalosis associated with?

Answer 117

Hypokalaemia

Question 118

Why is metabolic alkalosis associated with hypokalaemia?

Answer 118

Because it makes the intracellular pH acidic, favouring H+ excretion and HCO3- recovery

Question 119

Why can having a shabangover cause [HCO3-] to increase?

Answer 119

Persistent vomiting

Question 120

What accompanies persistent vomiting?

Answer 120

Dehydration

Question 121

What happens when [HCO3-] increases due to persistent vomiting?

Answer 121

The kidneys cannot excrete HCO3- as they are trying to compensate for the dehydration. HCO3- and Na+ recovery is favoured to increase the osmolarity of the plasma and cause the osmotic movement of water. In this case, you cannot rely on the kidneys to correct the [HCO3-]

Question 122

What happens if you correct the dehydration by giving fluids after persistent vomiting?

Answer 122

HCO3- will be excreted very rapidly

Question 123

Does persistent vomiting cause metabolic acidosis or alkalosis?

Answer 123

Alkalosis

Question 124

What is the result of persistent vomiting causing metabolic alkalosis?

Answer 124

The body stops actively secreting H+, as it would make the metabolic alkalosis worse

Question 125

What is the result in the decrease of H+ secretion in vomiting induced metabolic alkalosis?

Answer 125

As H+ secretion has stopped, so has K+ reabsorption, meaning that a dangerous side effect of persistent vomiting is hypokalaemia

Question 126

Why does a decrease in H+ secretion cause a decrease in K+ reabsorption?

Answer 126

Because it stops the antiporter in intercalated cells

Question 127

What does hypokalaemia cause?

Answer 127

Paresthesia
Tetany
CVS problems
bad times all round

Question 128

When will metabolic acidosis occur?

Answer 128

• If there is excess metabolic production of acids
• If acids are ingested
• If HCO3- is lost
• If there is a problem with the renal excretion of acid

Question 129

What acids may be metabolically produced?

Answer 129

• Lactic acid

- Ketones

Question 130

What happens if excess acid is produced?

Answer 130

The associated anion, e.g. lactate in lactic acid, will replace HCO3- in the plasma

Question 131

What is the result of the associated anion replacing HCO3- in the plasma when excess acid is produced?

Answer 131

This will influence the anion gap

Question 132

What is the anion gap?

Answer 132

The difference between the sum of the measured concentrations of Na+ and K+ and the sum of the measured concentrations of Cl- and HCO3-

Question 133

When will the anion gap increase?

Answer 133

If HCO3- is replaced by another anion, which is not included in the calculation

Question 134

When is the anion gap less likely to change?

Answer 134

If the problem causing metabolic acidosis lies within the renal excretion of H+

Question 135

Why will the anion gap be less likely to change if the problem causing the metabolic acidosis lies within the renal excretion of H+?

Answer 135

It will change the [HCO3-] directly, without replacement by an unmeasured ion