Lecture 19 - Renal Acid-Base

Question 1

This is an acid excreted from the lungs. What is an example?

Answer 1

volatile acid; carbon dixoide

Question 2

This substance receives H+ ions

A. acid
B. base
C. Volatile compound
D. Non-volatile compound

Answer 2

B. base

Question 3

This is the classification of acids excreted from kidneys. What is it called? Give an example.

Answer 3

Non-volatile (or “fixed”) acid; sulphuric acid, phosphoric acid, ketoacids

Question 4

-log[H]+

A. pKa
B. pKb
C. pH
D. pOH

Answer 4

C. pH

Question 5

What is the normal pH of arterial blood?

A. 7.37-7.44
B. 7.35-7.45

Answer 5

A. 7.37-7.44

Question 6

What is the KEq?

Answer 6

The dissociation constant for a given reaction. It is the ([product]/[reactant])

Question 7

What is the normal pH range for venous blood?

A. 7.37-7.44
B. 7.35-7.45

Answer 7

B. 7.35-7.45

Question 8

This compound dissociates to release H+

A. Acid
B. Base
C. Volatile chemical
D. Non-volatile chemical

Answer 8

A. Acid

Question 9

These are capable of reversibly binding H+

A. Acid
B. Base
C. Buffer
D. Hydroxide ions

Answer 9

C. buffer

Question 10

What are the components of the bicarbonate buffer system?

Answer 10

weak acid;

bicarbonate salt

Question 11

In the bicarbonate buffer system, the strength of the product is (proprtional/inversely proportional) to the strength of the added reactant.

Answer 11

Inversely proportional;

Example: the addition of a strong acid forms a weak acid. This is how the buffer system works. Strong acids produce weak acids, which do not readily dissociate. These weak acids “trap” H+, and prevent large changes in pH

Question 12

The most important ECF buffer system is the:

a. Protein buffer system
b. Bicarbonate buffer system
c. Phosphate buffer system

Answer 12

b. Bicarbonate buffer system

Question 13

Increased [H+] in the bicarbonate buffer system results in increased _____ via carbonic anhydrase. How is this product excreted?

Answer 13

CO2;

by increasing the respiratory rate

Question 14

Metabolic acid-base disorders are the result of __________.

Answer 14

changes to [HCO3]

Question 15

Respiratory acid-base disorders are the result of _________.

Answer 15

changes to [H+], typically due to a respiratory problem.

Question 16

The most important renal tubular fluid buffer system is the:

a. Protein buffer system
b. Bicarbonate buffer system
c. Phosphate buffer system

Answer 16

c. Phosphate buffer system

Question 17

The primary method for removal of non-volatile acids is through ___________.

Answer 17

renal excretion

Question 18

Reabsorption of HCO3 requires the HCO3 to react with ____ prior.

A. H+
B. H20
C. CO2
D. Na+

Answer 18

A. H+

Question 19

What are the 3 mechanisms of ECF [H+] regulation?

Answer 19

1) Reabsorption of filtered HCO3
2) Secretion of H+
3) Production of new HCO3

Question 20

Where in the kidney tubules does H+ ion secretion occur?

Answer 20

Secondary active transport - everywhere except thin asc./desc. Loops of Henle

Primary - late distal tubule’s intercalated cells

Question 21

Where in the kidney tubules does bicarbonate reabsorption occur?

Answer 21

PCT

Question 22

Describe the mechanism by which bicarbonate ion is reabsorbed.

Answer 22

Bicarbonate is filtered at the glomerulus, and H+ is secreted by tubular cells. These combine to form carbonic acid, which dissociates into water and carbon dioxide.

The CO2 diffuses into the tubular cells and combines again with water, forming carbonic acid again.

This carbonic acid then dissociates into HCO3 and H+.

The HCO3 then diffuses across the basolateral membrane and back into blood.

Question 23

What is the function of carbonic anhydrase?

Answer 23

To form carbonic acid in tubular cells.

Question 24

Is the HCO3 in the ECF the same as the HCO3 filtered at the glomerulus? Why or why not?

Answer 24

No. The HCO3 that is reabsorbed into the blood arises from the dissociation of the H2CO3 formed by carbonic anhydrase in the tubular cell.

Question 25

Describe what is meant by “incomplete titration.”

Answer 25

Incomplete titration occurs when there is not a 1:1 ratio of H+:HCO3 excretion. Instead, HCO3 can be reabsorbed to correct acidosis (completing the titration). Or, HCO3 can be excreted in the urine to correct metabolic alkalosis.

Question 26

Intercalated cells can secrete H+ ions into the tubular lumen via ____.

a. primary active transport
b. secondary active transport

Answer 26

a. primary active transport

Question 27

H+ ATPase pumps act to remove hydrogen following carbonic acid dissociation in tubular epithelial cells. Where are these H+ ATPases located?

A. PCT
B. Loop of Henle
C. Intercalated cells - late DCT
D. Principal cells - late DCT

Answer 27

C. Intercalated cells - late DCT

Question 28

H+ can also be removed by Na/H+ counter transport. Where does this occur?

A. PCT
B. Loop of Henle
C. Intercalated cells - late DCT
D. Principal cells - late DCT

Answer 28

A. PCT

Question 29

What is the lower limit of pH that the kidneys can achieve?

A. 4.0
B. 4.5
C. 5.0
D. 5.5

Answer 29

B. 4.5

Question 30

Excess H+ generation primarily occurs through:

A. failure to completely titrate H+ to HCO3
B. through protein metabolism
C. through improperly functioning phosphate buffer system

Answer 30

B. through protein metabolism

Question 31

Why can only a small amount of free H+ be excreted in urine daily?

Answer 31

In order to excrete all free H+, urine output would have to increase dramatically (to approximately 2,667 L/day)

Question 32

What two buffer systems play an important role in the excretion of large amounts of H+?

Answer 32

Phosphate and ammonia buffer system

Question 33

How do phosphate and ammonia buffer systems generate “new” bicarbonate?

Answer 33

The excess H+ is bound to phosphate and ammonia buffer systems. Therefore, HCO3 remains unbound and free in the system. That HCO3 then is returned to the blood, generating “new” HCO3.

Question 34

Excess base is handled by increased HCO3 excretion. By what mechanism does this occur?

Answer 34

By failing to resorb excess base.