Acid Base Balance 2

Question 1

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

Answer 1

• Kidneys regulate plasma [HCO3-]
• Urine pH is 5.8-6 (acidic relative to plasma pH)
• Filtered HCO3^- completely reabsorbed
  
  • HCO3^- freely filtered at glomerulus
• Kidneys secrete H+
  
  • Protons accepted by urinary buffers (phosphate and ammonia)
• HCO3- can also be newly formed in renal tubules
  
  • Replenish HCO3^- lost by buffering nonvolatile acids (sulfate or lactic acid)

-Excrete sulfate and phosphate (non-volatile acids)

Question 2

Give an overview of a nephron and Reabsorption of bicarbonate

Answer 2

For every bicarbonate reabsorbed, one H+ must be secreted unto t7bukar lumen

Bucarbonate Reabsorption in various parts of renal tubule

All filtered HCO3^- is reabsorbed (No HCO3^- in urine)

Question 3

Explain Reabsorption of filtered bicarbonate

Answer 3

1. Formation of carbonic acid (H2CO3) by carbonic anhydrase in tubular cell
2. Dissociation of carbonic acid (weak acid) to bicarbonate and proton
3. Secretion of proton into tubular lumen (via Na+ -H+ exchanger)
4. To maintain electrical neutrality, bicarbonate enters blood (for every proton secreted into lumen, one bicarbonate enters blood)
5. Secreted portion associated with filtered bicarbonate in tubular lumen to form carbonic acid
6. Carbonic anhydrase in brush border of tubular cells converts Carbonic acid to CO2 (which may diffuse into tubular cell to be reused)
7. 85% of filtered bicarbonate is reabsorbed in proximal tubule; rest in distal tubule

When secreted proton buffered by bicarbonate buffer in tubular lumen= Reabsorptionof filtered bicarbonate

Question 4

Summarize the formation of ‘NEW’ bicarbonate

Answer 4

When H+ ions (metabolism) added, HCO3- used to buffer H+
HCO3- levels fall

50-100 mEq non-volatile acid/day

If kidney does NOT form new bicarbonate, serum HCO3^- levels decrease

Two mechanisms form NEW bicarbonate (non-bicarbonate buffers)-very active in collecting duct

• phosphate buffer system
• ammonia buffer system

Question 5

What is the secretion of protons in the fold of phosphate buffer/ formation of ‘NEW’ bicarbonate?

Answer 5

1. Formation of carbonic acid (H2CO3) by carbonic anhydrase in tubular cell
2. Dissociation of carbonic acid (weak acid) to bicarbonate and proton
3. Secretion of H+ into tubular lumen
4. To maintain electrical neutrality, a bicarbonate enters blood (For every proton secreted into lumen, a bicarbonate enters the blood)
5. Proton associates with filtered phosphate to form acid phosphate (alpha-intercalated cells in distal tubule)
6. Acid phosphate excreted in urine and contributes to titratable acidity in urine.

When secret3d proton buffered by a non-bicarbonate buffer (phosphate/ammonia) in t7bukar lumen= formation of NEW bicarbonate

Question 6

Explain the role of ammonia in formation of new bicarbonate

Answer 6

1. Formation of carbonic acid (H2CO3) by carbonic anhydrase in tubular cell
2. Dissociation of carbonic acid (weak acid) to bicarbonate and proton
3. Secretion of H+ into tubular lumen
4. To maintain electrical neutrality, a bicarbonate enters blood (For every proton secreted into lumen, a bicarbonate enters blood)
5. Hydrolysis of glutamine by glutaminase forms ammonia in renal tubule
   - NH3 is lipid soluble and diffuses into tubular lumen
6. NH3 binds to secreted proton in tubular lumen to form ammonium ion(NH4-)(pk=9.2)—>. Trapped in lumen (distal tubule and collecting duct)
7. NH4^+ excreted as ammonium chloride in urine
8. Tubular capacity to excrete ammonium is unlimited and highly stimulated in prolonged acidosis.

When secreted proton buffered by a non-bicarbonate (phosphate/ammonia) in tubular lumen = formation of NEW bicarbonate

Question 7

Describe H+ secretion in collecting duct

Answer 7

H+ ATPase

K+ H+ ATPase

Secreted protons buffered by:

• HPO4^- to form acid phosphate (NaH2PO4^-)
• NH3 to form NH4+Cl (urinary ammonium chloride/sulfate)

Question 8

Describe bicarbonate secretion in urine

Answer 8

Beta-intercalated cells (collecting duct)

• Secrete HCO3- in urine
• Reabsorb H+
• Makes urine alkaline
• Active in chronic alkalosis

Question 9

How can we quantify urinary acid loss?

Answer 9

H+ in urine = acid phosphate (titratable acidity) + ammonium- urinary bicarbonate

Chronic acidosis —> increased H+ secretion in tubules and increased urinary acid phosphate and ammonium excretion

Chronic alkalosis—> decreased H+ secretion in tubules and decreased urinary acid phosphate and ammonium. Tubules secrete bucarbonate which is lost in urine

Question 10

What are the factors that increase H+ secretion in renal tubules ?

Answer 10

• Increased PCO2 (respiratory acidosis)
• Decreased pH (acidosis)
• hypokalemia
• Increased aldosterone
• Decreased ECF volume
• Diuretics (increase sodium load in renal tubules)

Question 11

Describe H+ and K+. Interrelations

Answer 11

K+ (major intracellular cation)

K+ and H+ are closely related

Diabetes mellitus: insulin deficiency and hyperglycemia (hyper osmolarity)—> K+ shift from ICF to ECF (hyperkalemia)

Changes in pH affect serum (ECF) K+ levels

• metabolic acidosis- hyperkalemia
• metabolic alkalosis- hypokalemia

Also, changes in serum K+ affects pH

• Hyperkalemia- acidosis
• Hypokalemua- alkalosis

Question 12

What is the relevance of potassium in metabolic acid-base disturbance ?

Answer 12

• In metabolic acidosis, excess H+ from ECF enters into ICF
• Intracellular K+ moves to ECF (hyperkalemia)
• Metabolic acidosis usually accompanied by hyperkalemia

Metabolic alkalosis associated with shift of K+ into ICF (hypokalemia)

Question 13

What is the effect of hypokalemia effect alkalosis?

Answer 13

-Low serum K+ levels facilitates entry of H+ into cells (ECF alkalosis)

• Effect of Hypokalemia on renal tubules
  
  • stimulates H+ secretion into lumen
  • Stimulates ammonia formation
  • stimulates formation of new HCO3 and increases serum HCO3 (alkalosis)

Hypokalemia maintains and worsens alkalosis

Question 14

Whaat is primary hyperaldosteronism(Conn’s syndrome)?

Answer 14

• Aldosterone stimulates Reabsorption of Na+ (increases serum Na+ levels and blood volume- hypertension )
• stimulates K+ excretion in urine(hypokalemia)
• stimulates renal tubular H+ ATP?ase(alkalosis)

Question 15

How does decreased ECF (volume contraction) effect RAAS?

Answer 15

Stimulates RAAS secretion

Angiotensin II increases Na-H anti porter to increase Na Reabsorption (H+ secreted —> increased Reabsorption of HCO3)

• Aldosterone increases sodium Reabsorption + CL- and H2Oreabsorption
• Stimulates H+ secretion (ENaC reabsorbs Na and lumen becomes negative- So, H+ is secreted by A-intercalated cell)
• Volume contraction and metabolic alkalosis, there is increased Na+ Reabsorption (to increase blood volume) and H+ secretion in urine (paradoxical aciduria)

Question 16

Contrast loop and thiazide diuretics

Answer 16

Loop diuretics-decrease Na+ Reabsorption in loop of henle
-result = decreased Na+ Reabsorption- -> increased Na+ delivery to the distal tubule

Thiazides- decrease Na+ Reabsorption in distal convuluted tubule
-result= decreased NaCl Reabsorption

Question 17

What are the similarities of loop diuretics and thiazide diuretics ?

Answer 17

Both cause ECF volume contraction —> secretion of aldosterone and angiotensin II

Decreased Na+ Reabsorption in tubules leads to increased Na+ delivery to distal tubule leads to K+ secretion and increased proton secretion leading to metabolic alkalosis and hypokalemia

Question 18

What are the factors affecting tubular H+ secretion?

Answer 18

• Decreased intracellular pH (acidosis)
• Increased PCO2 (respiratory acidosis)
• Increased plasma aldosterone
• Hypokalemia
• Increased Na+ Reabsorption (volume contraction)
• Inhibition of carbonic anhydrase (Acetazolamide)- decreases H+ secretion

Question 19

Describe renal compensation in respiratory/metabolic acidosis

Answer 19

Chronic acidosis (if kidney normal)

• increased H+ secretion by tubule
• Filtered bicarbonate is reabsorbed
• Urinary Acid phosphate (titratable acidity) is increased
• Ammonium in urine is increased
• Urine pH becomes acidic

Increased phosphate and ammonium excretion in urine

Question 20

Describe renal compensation in respiratory/metabolic alkalosis

Answer 20

• Alkalosis (if kidney normal and fluid volume normal)
• Decreased H+ secretion by tubule
• Filtered bicarbonate NOT reabsorbed.
• Urinary bicarbonate loss increases
• Acid phosphate and ammonium in urine decreases
• Bicarbonate also secreted by tubular cells
• Urine pH b3comes alkaline

Question 21

What are the mechanisms to maintain acid base homeostasis?

Answer 21

Buffers- ECF and ICF buffers are the first line of defense
 Bicarbonate (ECF)
 Phosphate(ICF and urine)
 Proteins(RBC and ICF)
 Ammonia (urine)

Respiratory system (responds in minutes)
Removal of CO2
Rate of respiration regulates PCO2

Renal system (responds in hours-days)
Reabsorption of HCO3^-
Maintenance of serum HCO3^- levels (form NEW HCO3^-)
Excretion of H+
Excretion of non-volatile acids (sulfate, phosphate, lactate)

Question 22

Contrast acidosis disorders

Answer 22

Respiratory acidosis -pH less than 7.4
PCO2: increased

Metabolic acidosis- pH less than 7.4
HCO3: decreased

Question 23

Contrast alkalosis disorders

Answer 23

Respiratory alkalosis: pH: increased 7.4
PCO2: decreased

Metabolic alkalosis: pH above 7.4

HCO3: increased