Acid/Base balance

Question 1

What’s the normal pH of the body? What concentration of H+ does this correlate to?

Answer 1

pH = -log[40*10^-9 eq/L] = 7.4

Question 2

Which processes in the body produce acid?

Answer 2

Your body produces lots of acid: oxidation of amino acids, fats, carbs

Question 3

What’s the major buffer we care about and why?

Answer 3

HCO3: it’s generated by the body

Its pKa is close to the body’s pH = 6.1

All the buffers are reflective of one another: the state of one is comparable to the state of another

Question 4

Henderson Hasselbach Equation

Answer 4

pH = pKa + log [HCO3]/alpha*pCO2

pKa=6.1

alpha=0.03

Question 5

What’s the kidney’s role in acid base balance?

Answer 5

Makes bicarb to replace what we lose in the lungs and in the kidney

Each day we lose 100 mEq of bicarb assuming 100 kilos body weight

HCO3 + H+ <–> H2CO3 <–> CO2 + H2O

Question 6

How does the kidney reabsorb HCO3?

Answer 6

Via H+ secretion, in the proximal collecting tubule and collecting duct

(1) H+ is secreted, combines with bicarb in the urine to form H2O and CO2
(2) the CO2 goes back into the cell

Question 7

Where is most of the bicarb reabsorbed?

Answer 7

In the proximal tubule, because it comes first! by the time it gets to the CD most of the bicarb is gone

Question 8

What’s the difference between bicarb reabsorption/H+ secretion in the PCT and CD?

Answer 8

(1) different channels: in PCT, it’s a Na/H exchanger that absorbs Na, pumps out protons; H+ combines with bicarb forming CO2 and H2O, and the CO2 goes back into the cell, becomes bicarb, which is pumped back into the blood with bicarb/Cl- exchanger

In the CD, it’s a H+ transloc. ATPase = pump (allows you to create up to 1000 fold gradient of H+); the H+ combines with NH3 to be excreted

(2) By the time the urine gets to the CD, not much bicarb will be left; each H+ will remain in the urine and not be balanced by a return of a bicarb! This is so great because this is how the body gets a net gain of bicarb

Question 9

What limits the capacity of the proximal tubule to reabsorb HCO3?

Answer 9

If the concentration of HCO3 increases too much

At a certain point, the reabsorptive capacity is saturated and HCO3 has a net excretion

Question 10

What regulates HCO3 reabsorption into the proximal tubule?

Answer 10

Volume depletion –> increased reabsorption

Osmotic/hydrostatic forces

Ang II directly stimulates Na/H exchanger: Na in, H+ out, so CO2 is reabsorbed

Question 11

What regulates H+ transport?

Answer 11

pCO2 = most important

aldosterone

K+

Acid-base status

NH3

pH gradient

Membrane potential (determined by Na absorption; when urine is neg, more H+ flows in)

Question 12

How does pCO2 regulate H+ transport?

Answer 12

High CO2 stimulates exocytosis of H+ ATP vesicles in proximal and collecting tubules

Question 13

How much acid do we actually excrete? How is this possible based on the pH/ volume of urine excrete/day? seems paradoxical

Answer 13

60 mEq/day

if the urine pH= 4.5-5, at a minimum we excrete 1L/day, so it’s only 10 microEq H+

Acid excretion is by other means than just “naked” protons: NH3 (generated from gluconeogenesis in kidney), HPO4

Question 14

Whats the relationship between acid ingestion and NH3 synthesis?

Answer 14

Directly related