Session 5: Control of plasma pH

Question 1

Normal pH range of blood plasma

Answer 1

7.35-7.45

Question 2

What is a blood plasma pH below its range called?

Answer 2

Acidaemia

Question 3

What is a blood plasma above its range called?

Answer 3

Alkalaemia

Question 4

Explain the effects of alkalaemia.

Answer 4

It reduces the solubility of Ca2+ which means that free Ca2+ leaves the ECF and binds to bone and proteins.

This leads to the classic symptoms of hypocalcaemia.

These include paraesthesia and tetany.

At 7.55 mortality rate is 45%

At 7.65 mortality rate is 80%

Question 5

Explain the effects of acidaemia

Answer 5

Increased H+ concentrations affects enzyme function by denaturing proteins. This leads to effects on muscle contractility, glycolysis and hepatic function.

It also leads to potassium movement out of the cells leading to hyperkalaemia which can be fatal as it can lead to arrhythmia etc.

Question 6

The H+ concentration in ECF is very low so just a very small change in amounts of acid would change pH drastically.

Why is this not the case?

Answer 6

Because H+ ions are buffered by binding to various sites.

Question 7

What is the most important ECF buffer for H+ ions?

Answer 7

The carbon dioxide/hydrogen carbonate system.

Question 8

Explain the CO2/HCO3- buffer system.

Answer 8

Dissolved CO2 reacts with water to form H+ and HCO3-

The pH depends on how much CO2 reacts to form H+.

Question 9

The ratio depends of HCO3- concentration to pCO2 (which in its way leads to CO2 concentration).

How is the pCO2 controlled?

Answer 9

By the lungs

Hyperventilating decreases pCO2

Hypoventilating increases pCO2

This is controlled by chemoreceptors

Question 10

How is the HCO3- controlled?

Answer 10

Largely created by reactions in the red cells but whose concentration is controlled by the kidneys.

Question 11

What disturbs the pCO2?

Answer 11

Respiratory disease

Question 12

What disturbs the HCO3- concentration?

Answer 12

Metabolic or kidney disease

Question 13

Briefly explain how the kidneys control pH.

Answer 13

Recovery of bicarbonate

Active secretion of H+

Question 14

What is the normal range of pCO2 in the arterial blood?

Answer 14

4.7-6.0

Question 15

Where is HCO3- filtered?

Answer 15

At the glomerulus

Question 16

Where is HCO3- reabsorbed?

Answer 16

Mostly in the PCT (80%)

Up to 15% of HCO3- is also absorbed in the thick ascending limb of the loop of Henle.

Question 17

Explain the basic renal control of HCO3-.

Answer 17

In the tubular cells CO2 and water react to form H+ and HCO3-. This is a reversible reaction.

However the H+ and HCO3- are transported out. H+ in exchange for Na+ to end up in the lumen of the tubule.

HCO3- is transported into the blood along with Na+.

The H+ that ends up in the lumen makes the ultrafiltrate acidic and it doesn’t want to be. The H+ therefore binds to HCO3- in the lumen of the tubule and produces H2O and CO2. H2O and CO2 can freely diffuse into the tubular cell again in order to provide more to the reaction creating more H+ and HCO3- again.

This allows HCO3- to be reabsorbed again.

Question 18

Explain the buffering system and HCO3- reabsorption in the distal convoluted tubule.

Answer 18

HCO3- absorption and H+ excretion in the distal tubule through its intercalated cells.

Here H+ is actively secreted via a H+-ATPase. This is because the Na+ gradient is insufficient to drive H+ out of the cell. Also not a lot of HCO3- is still available in the DCT lumen so little CO2 will enter the cell to react with water and produce more H+ and HCO3-.

So H+ will need another buffer which is HPO42- which becomes more effective as the pHof the ultrafiltrate falls.

HPO24- reacts with H+ to create H2PO4-

The active secretion of H+ leads to more H+ to be created in the CO2/HCO3- reaction.

HCO3- is transported into the capillary in exchange for Cl-.

Question 19

The total buffering capacity of phosphate and the other weak acids is limited by the amount filtered. Replacement of any further HCO3- needs to take place by a mechanism within the kidney.

What is this mechanism?

Answer 19

Excretion of ammonium ions by the production of the amino acid glutamine.

Question 20

Explain the glutamine reaction and its purpose.

Answer 20

Glutamine is converted into NH4+ and alpha-ketoglutarate.

The alpha-ketoglutarate is the converted into two HCO3-. The HCO3- is transported into the capillaries along with Na+.

The ammonium is converted into NH3 and H+.

The NH3 can freely diffuse into the lumen of the proximal convoluted tubule. In the lumen the ammonia NH3 will react with H+ to produce NH4+.

Question 21

Why is acid excretion important?

Answer 21

To keep HCO3- concentrations normal.

Question 22

Explain how acidosis leads to hyperkalaemia.

Answer 22

Potassium ions move out of cells

Decreased potassium excretion in distal nephron

Question 23

Explain how alkalosis leads to hypokalaemia.

Answer 23

Potassium ions move into cells

Enchance excretion of potassium in distal nephron.

Question 24

Explain acid base disturbances and potassium in hyperkalaemia.

Answer 24

Hyperkalaemia makes the intracellular pH of tubular cells more alkaline.

This leads to H+ moving out of the cells. This leads to HCO3- excretion and metabolic acidosis.

Question 25

Explain acid base disturbances and potassium in hypokalaemia.

Answer 25

Makes the intracellular pH of tubular cells more acidic.

H+ ions move into the cells and this favours H+ excretion and HCO3- recovery. This leads to metabolic alkalosis.

Question 26

What happens in hypoventilation to pCO2?

Answer 26

Hypercapnia (increased pCO2)

Question 27

What happens to plasma pH due to hypercapnia?

Answer 27

Plasma pH decreases

Question 28

What is respiratory acidaemia and what are is pCO2, HCO3- and pH in it?

Answer 28

When pCO2 rises due to hypoventilation or other lung disease where you can’t expirate correctly.

High pCO2.

Normal HCO3-

Low pH

Question 29

What is respiratory alkalaemia and what are the levels of pCO2, HCO3- and pH in it?

Answer 29

Due to hyperventilation leading to hypocapnia which is a fall in pCO2.

The hypocapnia (fall in pCO2) leads to a rise in pH.

HCO3- stays the same.

Question 30

How is respiratory acidosis compensated?

Answer 30

Kidneys increase HCO3- concentration.

Question 31

How is respiratory alkalosis compensated?

Answer 31

By the kidneys by decreasing HCO3-.

Question 32

How long does it take for the compensation mechanism by the kidneys?

Answer 32

Around 2-3 days

Question 33

What is compensated respiratory acidosis characterised by?

Answer 33

High pCO2

Raised HCO3- conc

Relatively normal pH

Question 34

What is compensated respiratory alkalosis characterised by?

Answer 34

Low pCO2

Low HCO3- conc.

Relatively normal pH

Question 35

Explain metabolic acidosis.

Answer 35

Tissue produce acid which reacts with HCO3- which removes it.

Leads to a fall in HCO3-. This leads to a fall in pH.

Question 36

What is metabolic acidosis initially characterised by?

Answer 36

Normal pCO2

Low HCO3- conc

Low pH

Question 37

Explain the compensatory mechanism in metabolic acidosis.

Answer 37

Peripheral chemoreceptors in the carotid bodies detect the pH drop. This leads to an increase in ventilation -> hyperventilation to lower pCO2.

Question 38

What is compensated metabolic acidosis characterised by?

Answer 38

Low HCO3-

Lowered pCO2

Nearer normal pH

Question 39

What is metabolic alkalosis characterised by?

Answer 39

Normal pCO2

Raised HCO3-

Increased pH

Question 40

Explain the compensatory mechanism of metabolic alkalosis.

Answer 40

Cannot be easily corrected by decreased ventilation since that would lead to hypoxia.

Instead a rise in pH of tubular cells leads to a fall in H+ excretion and a reduction in HCO3- recovery.

Question 41

Explain the anion gap.

Answer 41

The difference between measured cations and anions.

(Na+ + K+) - (Cl- + HCO3-)

Question 42

What is the anion gap normally?

Answer 42

10-18 mmol/l

Question 43

When is the anion gap increased?

Answer 43

If HCO3- is replaced by other anions

Question 44

Conditions leading to respiratory acidosis.

Answer 44

Type 2 respiratory failure like severe COPD, severe asthma, drug overdose or neuromuscular disease where pO2 is low and pCO2 is high.

Question 45

Conditions leading to respiratory alkalosis.

Answer 45

Hyperventilation due to e.g. panic attacks and/or anxiety. Low pCO2 and a rise in pH.

Hyperventilation in response to long-term hypoxia in type 1 respiratory failure.

Question 46

Conditions leading to metabolic acidosis with an increased anion gap.

Answer 46

Keto-acidosis like diabetes

Lactic acidosis like exercising to exhaustion or poor tissue perfusion.

Uraemic acidosis in advanced renal failure with reduced acid secretion, build up of phosphate, sulphate and urate in blood.

Question 47

When in metabolic acidosis can the anion gap be normal?

Answer 47

If anion gap is normal HCO3- is replaced by Cl-.

Question 48

Conditions leading to metabolic acidosis with a normal anion gap.

Answer 48

Renal tubular acidosis where there are problems with transport mechanisms in the tubules.

Severe persistent diarrhoea leading to metabolic acidosis due to loss of HCO3- which is replaced by Cl-

Question 49

Explain the potassium concentrations in metabolic acidosis due to diabetic ketoacidosis.

Answer 49

Usually acidosis leads to hyperkalaemia.

However in diabetic ketoacidosis there may be a total body depletion of K+.

Initially K+ moves out of the cells due to the acidosis and the lack of insulin. However the osmotic diuresis leads to K+ being lost in urine.

Then giving insulin to these patients makes K+ move into cells again and can lead to hypokalaemia instead.

Question 50

Conditions leading to metabolic alkalosis.

Answer 50

HCO3- is retained in place of Cl-.

Severe prolonged vomiting leading to loss of H+ as the stomach is a major site of H+ secretion and also HCO3- production.

Potassium depletion and mineralcorticoid excess.

Loop diuretics and thiazides

Question 51

Explain how metabolic alkalosis is corrected in persistent vomiting.

Answer 51

HCO3- increase after persisting vomiting as H+ is excreted and more HCO3-.

Rise in pH of tubular cells leads to fall in H+ excretion and reduction in HCO3- recovery.

Question 52

Why might there be a problem with the compensation of metabolic alkalosis due to peristent vomiting.

Answer 52

If there is also volume depletion the capacity to lose HCO3- is reduced because of high rate of Na+ recovery to retain water.

Recovering Na+ favours H+ excretion and HCO3- recovery.

Question 53

If pCO2 is not normal, HCO3- conc is normal and pH has changed in the opposite direction to pCO2.

What will it be?

Answer 53

Respiratory alkalosis or acidosis

Question 54

If HCO3- is not normal, pCO2 is normal and pH has changed in the same direction as HCO3-.

What is it?

Answer 54

Metabolic acidosis/alkalosis