Metabolic acid base balance

Question 1

Describe normal pH and define acidosis and alkalosis

Answer 1

• normally pH is 7.4 and very tightly regulated within a normal range
• if higher than 8 or lower than 6.8 it is incompatible with life
• if pH is 7.35 or lower, this is termed acidosis (which depresses the CND, and leads to extreme conditions such as coma and respiratory failure)
• if pH is 7.45 or higher, this is considered alkalosis (stimulates SNS, and leads to extreme conditions such as muscle seizures and convulsions)
• Therefore, acidosis starts at an alkaline pH, but is acidic relative to the reference scale

Question 2

What are the consequences of metabolic acidosis and alkalosis?

Answer 2

• acidosis (which depresses the CND, and leads to extreme conditions such as coma and respiratory failure)
• alkalosis (stimulates SNS, and leads to extreme conditions such as muscle seizures and convulsions)

Question 3

Describe sources of acid input and output

Answer 3

input: diet and cellular metabolism
- output: hydrogen ions, handled by kidneys, and carbon dioxide, handled by the lungs
- layers of defence against pH disturbances: chemical buffering, pre-respiratory and renal responses (See also [[Physiology Lecture 6])] for buffers)

Question 4

What is the role of the kidney in acid base balance?

Answer 4

Kidneys excrete and reabsorb H and HCO2
- kidneys are responsible for 25% compenstation of acids not handled by lungs
- they do this via direct and indirect mechanisms
- directly: excreting or reabsorbing hydrogen ions
- indirectly: excreting or reabsorbing bicarbonate buffer

Question 5

Describe the actions of the kidney in acidosis and alkalosis

Answer 5

In acidosis the kidneys do two things:
- secrete hydrogen ions by primary and secondary active transport mechanisms. Examples include:
- buffering protons with ammonia and phosphate
- making new bicarbonate ions from carbon dioxide and water
- synthesise ammonia (HCO3 is a by-product of this process)

In alkalosis:
- processes are reversed: excrete the bicarbonate and reabsorb hydrogen ions (to help bring down the alkaline pH)

Question 6

True or false: renal compensation is the fastest mechanism of acid-base balance

Answer 6

FALSE - renal compensation is the slowest mechanism of acid-base balance

Question 7

List the transporters involved in renal handling

Answer 7

• Na+/H+ antiporter
• Na+/HCO3- symporter
• H+-ATPase
• H+/K+-ATPase
• Na+/NH4+ antiporter
• Na+/K+-ATPase
• HCO3-/Cl- antiporter

Question 8

What are the components of net urinary acid excretion?

Answer 8

NAE = excreted hydrogen ions bound to phosphate, uric acid and creatinine (filtered buffer, not synthesised by kidney) + excreted protons bound to ammonia (Synthesised buffer) - excretion of filtered bicarbonate ions

Question 9

Define titratable acid

Answer 9

The primary urinary buffer is phosphate (although there are others, a.k.a filtered buffers).
The urinary buffers are collectively referred to as titratable acids.

• protons transported into tubule using pump (H-ATPase or H/K ATP-ase)
• proton comes from carbonic anhydrase reaction (H2CO3–> Hco3- and H+)
• hydrogen ions binds with buffer in tubular fluid, to be excreted

Question 10

Describe reabsorption of bicarbonate and how it is regulated

Answer 10

• all HCO3 is essentially reabsorbed
• modulated by hydrogen ion/ proton secretion
• additionally, it is regulated by H concentration gradient: more H, more efficient
• activity and expression of key H and HCO3 transporters is also regulated and affects efficiency e.g. by acidity levels
  
  • in acidosis (secretion is favourable, therefore) increased H- ATPase in collecting duct, and Na/H antiporter and Na/3HCO3 expression and activity is increased in proximal tubule
  • in alkalosis (retention is favourable, therefore) the reverse effects, decreased H-ATPase in collecting duct and decreased Na/H and Na/3HCO3 expression and activity ^[in addition to any other effects?]

Question 11

Describe the relationship between plasma bicarbonate and urine bicarbonate

Answer 11

• similar to glucose pattern
• filtered and reabsorbed levels proportional to a point of saturated, then appear in urine i.e. excreted
• note threshold of plasma bicarbonate concentration before significant HCO3 appearance in urine is equivalent to normal plasma concentration
• therefore kidneys are well placed to excrete excess HCO3, minimising alkalosis

Question 12

Why are kidneys well placed to excrete excess bicarbonate?

Answer 12

• similar to glucose pattern
• filtered and reabsorbed levels proportional to a point of saturated, then appear in urine i.e. excreted
• note threshold of plasma bicarbonate concentration before significant HCO3 appearance in urine is equivalent to normal plasma concentration
• therefore kidneys are well placed to excrete excess HCO3, minimising alkalosis

Question 13

Describe reabsorption of bicarbonate

Answer 13

• proton concentration in tubule is key
• h2co3 formed
• ca on tubular side, results in co2 formed
• h2co3 reformed in cell
• ca leads to regeneration of hco3
• na/hco3 and cl/hco3 export HCO3 into blood
• Note: Na/K/ATPase contributes to exchanger function

Question 14

Does secretion of bicarbonate normally occur? If so, how?

Answer 14

Secretion of HCO3 in collecting duct
NOTE: ONLY in alkalosis
- co2 diffuses into cell
- hco3 exchanged for cl
- h pumped with ATPase into interstitial space and blood, helping to correct

Question 15

Describe the process of formation of new HCO3

Answer 15

For acid-base balance to be maintained, the kidneys must replenish any lost HCO3-
- This is achieved via 2 mechanisms
- Some of the HCO3- is produced during titration of urinary buffers in collecting duct
- note: not regulated by body’s requirement to maintain normal pH– non-specific process, simple buffering)
- 2nd mechanism is regulated
- synthesis of ammonia, producing bicarbonate
- occurs in early proximal tubule
- in mitochondria
- glutamine taken up from interstitial or tubule
- glutamine to glutamate
- glutamate to aKG
- both steps generate ammonium
- aKG to glucose requires protons, OH reacts with CO2 to form HCO3
- one glutamine = 2HCO3
- ammonium dissociates into ammonia, freely diffuses, h pumps out, forms ammonium again in tubule lumen

Question 16

Describe how ammonium is handled by the nephron

Answer 16

In PCT, glutamine is metabolised by the tubule cell. This generates 2 ammonium and 2 bicarbonate ions. Bicarbonate is re-absorbed into blood (e.g. via Cl/HCO3, Na/3HCO3).
NH4 dissociates into NH3 and H+ which diffuse/transport across apical membrane into tubule lumen
In thick ascending LOH, NH4 hijacks Na/K/2Cl symporter, takes K’s place
re-enters tubule cell
dissociates to NH3 and H+ in cell
diffuses into interstitial space and recombines to become NH4+, which is transported to liver (where it is combined with HCO3, produces urea and CO2)
The transport of NH4 to the liver needs to be minimised otherwise the HCO3 that is generated is used up. So if it does happen, it’s an “unintentional” process rather than the norm.
to minimise liver handling, NH4+ hijacks Na/K/ATPase to re-enter tubule cell, where it dissociates into NH3 and H+
then it diffuses out into tubule lumen, re-associates to form NH4+, and is excreted

Question 17

Describe the urine anion gap

Answer 17

• Urine must maintain macroscopic electroneutrality
• Na + K + NH4 = Cl and HCO3
• effectively Na +K + gap = Cl
• gap= Na + K - Cl
• gap is essentially a rough index of NH4 in urine
• should be zero or very slightly positive if normal NH4 production
• strongly negative with increased NH4 production
• strongly positive if production is impaired

provides clues as to origin of metabolic acidosis e.g. diarrhoea, correct for loss of bicarbonate by increasing NH4 production
- cannot be used in all instances e.g. high levels of excreted anions as is the case in ketoacidosis, affecting electical balance

not used much clinically

Question 18

Describe the types, causes and consequences of renal tubule acidosis

Answer 18

• renal acidification is impaired
• can be defect in proximal, distal or other
  
  • proximal causes: defect in proximal tubule proton secretion, which can be hereditary, or acquired e.g. CA inhibitors
  • proximal- consequences: decreased HCO3 absorption
  • distal causes: defect in distal tubule proton secretion, which can be hereditary, or acquired e.g. amphotericin B
  • distal- consequence: decreased excretion of titratable acid
  • other - causes: defect in NH4 production, such as in mild to moderate renal failure
  • other - consequences: decreased urinary NH4

All can lead to metabolic acidosis

Patients may need to ingest alkali to compensate, if RTA is severe

Question 19

Describe the plasma anion gap

Answer 19

• useful to determine cause of metabolic acidosis
• plasma, like urine, must maintain neutrality
• Na + other = cl and hco3 + others
• Na= Cl and hco3 (Aka majors)
• gap = Na -(cl + hco3)

Gap is normal with diarrhoea or RTAs previously discussed. High if ketoacidosis, lactic acidosis or aspirin overdose or overdose of negatively charged drugs.

Question 20

Describe paradoxical aciduria

Answer 20

• low urine pH in cases of metabolic alkalosis
• this occurs if volume loss occurs with hydrogen loss, as in vomiting
• therefore, bicarbonate excretion **does not occur
• this is because sodium reabsorption, or volume correction is stimulated, and takes priority over acid-base balance
• in turn this increases HCO3 reabsorption as a result of enhanced H secretion
• elevated aldosterone levels stimulate hydrogen secretion in the collecting duct, as well as modulating Na levels