Chapter 11: Acid-Base Balance During Exercise

Question 1

3 factors that H+ production depends on

Answer 1

1) exercise intensity
2) amount of muscle mass involved
3) duration of exercise

Question 2

how does the decline in blood pH compare to the decline in muscle pH?

Answer 2

muscle pH declines more dramatically than blood pH

Question 3

3 source of H+ ions during exercise

Answer 3

1) production of CO2
2) production of lactic acid
3) ATP breakdown

Question 4

where does carbon dioxide come from?

Answer 4

end product of oxidative phosphorylation (bicarbonate buffering reaction contributes the H+ ions with an increase in CO2)

Question 5

where does lactic acid come from?

Answer 5

glucose metabolism via glycolysis; lactic acid <—> lactate + H+

Question 6

how does ATP production result in H+ increase?

Answer 6

ATP + H2O <—> ADP + HPO4- + H+

Question 7

what types of sports/exercises promote acid-base disturbances in skeletal muscle?

Answer 7

higher intensity exercises lasting greater than 45 seconds (linked to effort/max effort)

Question 8

2 ways increased [H+] impairs performance

Answer 8

1) inhibits enzymes in aerobic and anaerobic ATP production
2) [H+] can impair muscle contraction by competing with Ca2+ for binding sites on troponin

Question 9

how is the acid-base balance maintained during exercise?

Answer 9

by buffers that releases H+ ions when pH is too high and accepts H+ ions when pH is too low

Question 10

5 cellular buffer systems (first line of defense against pH changes)

Answer 10

1) bicarbonate *
2) phosphates *
3) proteins
4) carnosine
5) transport of hydrogen ions out of muscle

Question 11

which have a higher buffering capacity: type I or type II?

Answer 11

type II muscle fibers have a higher buffering capacity

Question 12

how does high intensity exercise training improve the muscle buffering capacity?

Answer 12

by increasing carnosine and hydrogen ion transporters in the trained muscle fibers

Question 13

2 blood buffer systems (second line of defense against changes in pH)

Answer 13

1) respiratory compensation for metabolic acidosis
2) bicarbonate

Question 14

given the bicarb buffering equation:
CO2 + H2O <—> H2CO3 <—> H+ + HCO3-

how does decreasing pH lead to CO2 removal by lungs?

Answer 14

decreased pH (increased H+ ions) —> reaction moves to the left —> CO2 is removed by the lungs —> eliminating H+ and increasing pH

Question 15

what is ventilatory threshold caused by?

Answer 15

increasing blood PCO2 and H+ (increasing K+, increasing body temp, elevated blood catecholamines and neural influences may contribute as well)

Question 16

what group proves that lactic acid production does not cause the ventilatory threshold?

Answer 16

McArdle’s patients (they can’t produce lactic acid but they still experience a ventilatory threshold)

Question 17

how does arterial PO2 change during graded exercise in an untrained subject?

Answer 17

maintained within 10-12 mmHg of resting value; does not change much (not experiencing exercise-induced arterial hypoxemia)

Question 18

how does arterial PCO2 change during graded exercise in an untrained subject?

Answer 18

arterial PCO2 slightly decreases with maximal exercise (because of hyperventilation)

Question 19

how does arterial pH change during graded exercise in an untrained subject?

Answer 19

decreases with maximal exercise (increasing H+ production causes buffering systems to reach capacity)

Question 20

how does ventilation change during graded exercise in an untrained subject?

Answer 20

linear increase up to 50-75% VO2 max, then exponential rise

Question 21

are kidneys significant in maintaining the acid-base balance during exercise? why?

Answer 21

no, because there is decreased blood flow to the kidneys

Question 22

how do kidneys contribute to the acid-base balance at rest?

Answer 22

by regulating the blood bicarbonate concentration:
decreased blood pH (increased H+ ions) —> bicarbonate excretion by kidneys is reduced
increased blood pH (decreased H+ ions) —> bicarbonate excretion by kidneys is increased

Question 23

3 ways lactate can be removed following exercise

Answer 23

1) 70% of lactic acid is oxidized by heart and skeletal muscle to make energy
2) 20% converted to glucose via Cori cycle in the liver
3) 10% converted to amino acids

Question 24

what helps lactic acid removal after strenuous exercise?

Answer 24

lactic acid is removed more rapidly with light exercise in recovery (optimal intensity of recovery exercise is 30-40% VO2 max)