Regulation of K+ Balance + Intro DSA

Question 1

How does the cardiac conduction system respond to hyperkalemia?

Answer 1

the opposite of other cells!

hyperkalemia –> hyperpolarizes membrane –> high T waves

Question 2

What are the most important factors that stimulate potassium secretion?

Answer 2

1. Increased K in ECF
2. Aldosterone
3. Increased tubular flow rate

Question 3

What is pseudohyperkalemia?

Answer 3

artificially high plasma K levels due to lysis of RBCs while blood is drawn

Question 4

How does hyperkalemia affect membrane potential?

Answer 4

hypopolarizes the cell –> easier to depolarize and make action potential

Question 5

How does hypercalcemia affect membrane potential?

Answer 5

increases threshold –> cells are less excitable

Question 6

What is alkalemia?

Answer 6

physiologically high blood pH

Question 7

How does decreased flow rate affect K+?

Answer 7

K+ concentration builds up earlier in tubule –> concentration gradient decreased –> K+ secretion slows

Question 8

What are the most important factors that stimulate K reabsorption?

Answer 8

1. K+ deficiency, low K+ diet, hypokalemia
2. K+ loss through severe diarrhea

Question 9

Where is K+ found throughout the body?

Answer 9

98% intracellular

• 80% muscle cells
• 20% other cells

2% extracellular

Question 10

How do beta-catecholamines affect K?

Answer 10

enhance cell uptake

+ Na-K-ATPase via + cAMP

Question 11

How does increased flow rate affect K+?

Answer 11

increased flow rate dilutes K+ secreted into lumen –> increases K+ concentration gradient bc K+ is washed away –> delivers more Na+ to DT for reabsorption –> K+ secretion is promoted

Question 12

How does aldosterone affect serum K+ concentration?

Answer 12

lowers serum K

renal: increases K+ excretion
extrarenal: increases K+ secretion into intestinal fluids and saliva; enhances acid excretion via production of systemic alkalosis

Question 13

What is the normal dietary intake of calcium for an adult?

Answer 13

1000 mg/day

absorption best at <500 mg

Question 14

How does acute acidosis affect K+

Answer 14

decreased activity of Na-K-ATPase pump

decreased K+ brought into cells from IF

decreased K+ secretion

end result = hyperkalemia

Question 15

What occurs to K+ in the late DT and cortical CD?

Answer 15

secreted or reabsorbed according to the needs of the body

Question 16

Where is phophate distrubuted in the body?

Answer 16

85% bone

14% cells

1% serum

Question 17

How does the heart respond to hypokalemia?

Answer 17

the opposite of other cells

hypokalemia –> hypopolarized –> low T wave and tachycardia

Question 18

Where is magnesium distributed in the body?

Answer 18

50% in bone

49% in ICF

1% in ECF

Question 19

How does chronic acidosis affect K+?

Answer 19

chronic acidosis decreases reabsorption of water and solutes by PT by inhibiting NaKATPase –> increases tubular flow –> RAAS stimulated due to lack of water reabsorption –> ends up increasing K+ secretion

Question 20

What is normal total serum Mg?

Free?

Answer 20

total = 1.8 mEq/L

Free = 0.8 - 1.0 mEq/L

Question 21

How does cell damage affect K?

Answer 21

impaired cell uptake

release of intracellular contents

Question 22

How does increased NaCl reabsorption upstream affect K+ secretion downstream?

Answer 22

decreases it

bc less Na delivery to CNT and CCD –> decreases Lumen-negative potential difference

Question 23

What happens to K+ in Beta intercalated cells?

Answer 23

H+ /K+ antiporter on basolateral surface pulls in K+ from IF –> K+ flows down gradient into tubular lumen = K+ secreted

BS = beta secretes

Question 24

How does hyperosmolality affect K?

Answer 24

enhanced cell eflux H2O goes out of cells to balance –> K+ concentration in cells increases –> K+ goes out of cells down its gradient

Question 25

What is the recommended phosphorus intake?

How much is actually absorbed?

Answer 25

1500 mg dietary intake required

1100 mg absorbed

200 mg secreted into gut

~net 900 mg phosphorus absorbed per day

Question 26

What is K+ resorption like in the proximal tubule (in general)?

Answer 26

similar to Na+ resorption

plays an indirect role in regulation of K+ balance via NaCl reabsorption –> affects distal tubular flow –> impacts K+ later on

Question 27

What happens to K+ in principal cells of the collecting duct?

Answer 27

Na-K-ATPase pump on basolateral side pulls K in from the IF –> K exits and is secreted into tubular lumen via BK and ROMK ENaC pulls in Na from lumen and is target of aldosterone

Question 28

What happens to K+ in alpha-intercalated cells?

Answer 28

Alpha reAbsorbs K

H+/K+ antiporter on apical surface pulls in K+ –> goes down gradient and is reabsorbed

Question 29

What is the equation for filtered load?

Answer 29

GFR x plasma concentration x %filterability

Question 30

How does acute alkalosis affect K+?

Answer 30

increased activity of Na-K-ATPase

increased K brought into cells from IF

Increased K+ secretion

end result = hypokalemia (K+ is lo)

Question 31

What are the 4 steps of LoH transport and recycling of K+?

Answer 31

1. K+ secreted into cortical collecting duct
2. K+ reabsorbed by OMCD and IMCD
3. K+ floats in interstitium
4. K+ secreted into Late PT/descending thin limbs of LoH

Question 32

Via what mechanism is K+ reabsorbed in the PT?

Answer 32

paracellularly

Question 33

How does hypocalcemia affect membrane potential?

Answer 33

decreases threshold –> cells are more excitable

hypocalcemic tetany/spasticity

Question 34

How do alpha catecholamines affect K?

Answer 34

impaired cell uptake

• Na-K-ATPase via - cAMP

Question 35

How does epinephrine affect serum K+ concentrations?

Answer 35

lowers serum K increases uptake into extrarenal cells stimulates K excretion by the kidney

(differing response for alpha vs beta receptors)

Question 36

How do high sodium and flow rate relate?

Answer 36

High sodium or decreased aldosterone inhibits K+ secretion

High flow rate increases K+ secretion

counteract/balance each other out

Question 37

How does hypokalemia affect membrane potential?

Answer 37

hyperpolarizes cell – harder to make action potential

Question 38

What is alkalosis?

Answer 38

decrease in H+ ion concentration in the ECF

acute process

Question 39

How does anion deliver affect K+?

Answer 39

increases K+ secretion

Question 40

How does strenuous exercise affect K?

Answer 40

enhanced cell efflux

+ alpha catecholamines

Question 41

What is the goal of K+ recycling?

Answer 41

increase presence of medullary K+ –> decreases NKCC reabsorption by TAL –> enhanced Na delivery to distal tubule –> stimulates Na reabsorption and K+ secretion = helps you excrete more K+ during dietary load!!!

Question 42

What is the normal range of plasma K+ concentration?

Answer 42

3.5 - 5.0 mEq/L

Question 43

How does Insulin affect serum K+ concentration?

Answer 43

lowers serum K stimulates Na-K-ATPase –> flux of K+ into cells and efflux of Na+ out of cells

*insulin and glucose administration can treat hyperkalemia

Question 44

How is K+ reabsorption driven in the PT?

Answer 44

In early PT, Na reabsorbed primarily w/ HCO3- Cl- gets left behind –> - charges build up (TEPD) –> Cl- is repelled and reabsorbed –> water dragged along –> positive TEPD builds up as Cl- reabsorbed –> positive TEPD repels K+ –> K+ reabsorbed PARACELLULARLY