K+ Metabolism

Question 1

What compartment contains the majority of K+?

Answer 1

Our body approximately has 3000-4000 meq of K. 98% of the K is intracellular, intracellular storage contain about 3300 meq of K. Rest of the K about 2% is in the extracellular fluid (65 mEq)

Question 2

What is the intracellular conc of K+ normally?

Answer 2

about 150 meq/L

Question 3

What is the extracellular conc of K+ normally?

Answer 3

about 4.5 meq/LNOTE: when we check K+ in the body, it is the extracellular K+ we are checking

Question 4

What organs contain the most K+?

Answer 4

-muscle (2500 mEq)-liver (250 mEq)-RBC (250 mEq)-Bone (300 mEq)so damage to these will release large amounts of K+

Question 5

How much K+ is consumed in a normal diet? How is it excreted or is it retained?

Answer 5

~100 meq of K. If the kidney is functioning normally, about 90-95% of that is excreted through the kidney. NOTE: A minimal amount of K is excreted through large bowel in the stool.

Question 6

What is the result of most of K+ being intracellular?

Answer 6

Cellular damage will release large amount of K into the ECF. K conc in the extracellular fluid or blood can be changed by movement of small amount of K out of the large K storage in ICF or impairment of renal excretion of K.

Question 7

Note on internal vs. external K+ balance.

Answer 7

External balance involves K intake with diet and K excretion through kidney and GI tract. Internal balance of K is maintained by regulation of K distribution between intracellualr and extracellular compartments.

Question 8

Where is the majority of K+ reabsorbed?

Answer 8

PCT (65%)Thin ascending limb (25%)A small amount K is reabsorbed in the cortical and ssOUTER medullary collecting duct by the intercalated cells – but the amount is very small, and it usually only becomes significant in case of hypokalemia

Question 9

T or F. K that is secreted in urine mostly comes from K secretion from the principal cells in the collecting tubules in the cortex and in the outer medulla and also inner medullary collecting duct.

Answer 9

T.

Question 10

How is K+ absorbed in the TALH?

Answer 10

with the Na/K/2Cl transporter located in the luminal border

Question 11

What happens to the Na+ and Cl- that is absorbed?

Answer 11

Na+: returned to the systemic circulation by the NaK ATPase in the basolateral membraneCl-: The Cl is returned by a selective Cl channels in the basolateral membrane

Question 12

What happens to the K+ that is absorbed?

Answer 12

Some of the K that is reabsorbed is recycled back across the luminal membrane by a selective K channel (ROMK). ROMK (renal outer medullary potassium channel)

Question 13

What does the K+ transport back into the tubular lumen allow for?

Answer 13

1) continued function of the Na/K/2Cl transporter2) The K that comes out increases the lumen positivity and allows for passive paracellular transport of +ve charges such as K, Ca, Na, and Mg. to the ISF

Question 14

What does the drug Furosemide do?

Answer 14

inhibiting the NaK2Cl transporter (as does Bartter’s syndrome)

Question 15

Where is K+ secreted?

Answer 15

In principle cells of the Collecting duct (cortical and medullary)

Question 16

How does K+ secretion occur?

Answer 16

The K secretion is associated with Na reabsorption in the segment.

Question 17

How does Aldosterone affect K+ secretion in the principle cells of the CD?

Answer 17

Aldosterone after entering the cells combine with the specific aldosterone receptor in the cytosol.

Question 18

What does the aldosterone receptor do once bound?

Answer 18

The hormone receptor complex migrates to the nulceus where it forms new protein including Na and K channels for the apical membrane, and The positive effect of aldosterone on the NaK ATPase pump moves 3Na out of the cells and 2K into cells

Question 19

What does the movement of the NaK ATPase pump allow for?

Answer 19

The movement of Na outside the cells promotes passive diffusion of luminal Na into the cells. NOTE: Aldosterone promotes this passive diffusion by formation of newer Na channel

Question 20

What does movement of Na+ into the cell allow for?

Answer 20

Movement of the positively charged Na creates relative electronegativity in the lumen. To maintain the electroneutrality in the lumen K is passively secreted out of the cells into the tubular lumen mainly and Cl gets reabsorbed through the paracellular pathway to the ISF. NOTE: Aldosterone stimulates the synthesis and formation of K channel in the apical membrane.

Question 21

What things affect the amount of K+ secreted in the CD?

Answer 21

1. concentration gradient of K across the basolateral membrane – it depends upon serum K concentration2. The electrical gradient across the luminal membrane – it depends upon the reabsorption of Na through the Na channels in the luminal membrane. Which in turn depends upon the Na concentration in the tubular lumen via distal delivery of Na3. K+ permeability of the luminal membrane

Question 22

What is the effect of less Na being reabsorbed in the PCT or LOH?

Answer 22

More Na+ will be delivered to the collecting tubule which will cause more Na reabsorption by the ENa channel and more K secretion (loss in urine)On the other hand if we do not have enough distal Na delivery, it will impair K secretion in collecting tubule.

Question 23

What is K+ permeability of the luminal membrane in the CD affected by?

Answer 23

that depends upon the number of open K channel on the luminal membrane. Which is affected by the aldosterone.

Question 24

So what is the effect of hyperaldosteronism on K+?

Answer 24

increase K+ secretion and lead to low serum K or hypokalemia. On the other hand if Aldosterone level is low which is known as Hypoladosteronism will decrease K+ secretion and elevated serum k or hyperkalemia.

Question 25

How does increased distal tubular flow of Na affect distal K+ secretion?

Answer 25

On a control diet as the distal tubular flow increases distal K secretion also increases. This happens in presence of aldosterone. High K diet will enhance the effect of the distal tubular flow. The enhnaced K secretion associated with higher K diet can be explained by the other 2 factors that mentioned in the previous slide. High K diet will increase the serum K level which will increase the 1. K concentration gradient and as well as 2. serum aldosterone level. As a result distal K secretion is increased.

Question 26

On the other hand low K diet will reduce the distal K secretion. Why?

Answer 26

Even with increasing the distal tubular Na delivery K secretion will not increase, this happens because low K will remove stimulation of aldosterone secretion.

Question 27

What things can decrease K+ secretion?

Answer 27

-renal failure. -decreased distal tubular flow (dysfunctional CD) or delivery of Na+-hypoaldosteronism (will lead to hyperkalemia)

Question 28

What things can increase K+ secretion?

Answer 28

-increased distal Na+ delivery (loop diuretics, thiazides, Bartter’s and Gitelman’s)-impair proximal Na absorption-hyperaldosteronism (secondary or primary)

Question 29

How is internal K balance maintained?

Answer 29

by regulating the K transport across the cell membrane via a Na-K-ATPase pump that maintains high intracellular K+ levelsNOTE: Because of the high gradient some K+ comes out of the cells by passive transport through the K channel.

Question 30

There are several factors that promotes the K movement across the cell membrane. Name some.

Answer 30

-Plasma K concentration-Insulin-Epinephrine

Question 31

What does insulin do?

Answer 31

Insulin moves K inside the cells by stimulating a NaH exchanger on the cell membrane that moves Na inside the cell in exchange for H, this intracellular Na than activate the NaKATPase pump and moves K inside the cells.

Question 32

What does epi do?

Answer 32

activates the NaKATPase pump by stimulating beta2 receptors (Any other hormones or drugs, such as albuterol, that can stimulate beta receptor will stimulate NaKATPase pump.)

Question 33

What is the effect of diabetes or a BB on intracellular K+?

Answer 33

the activity of the NKATPase pump will be impaired, with decrease movement of K from ECF to ICF. But the K channel which is not affected by the hormones will remain open and will continue to move K ICF to ECF which will result in elevated K in ECF

Question 34

How do acid-base disturbances affect internal K+ balance?

Answer 34

extracellular acidosis promotes H+ movement inside the cell and K+ out and vice-versa with alkalosis

Question 35

T or F. Metabolic acid-base disturbances have a greater effect than respiratory disturbances.

Answer 35

T. Metabolic acidosis due to organic acids (ketoacidosis, lactic acidosis) have smaller effects than do acidosis due to mineral acids.

Question 36

How does plasma tonicity or osmolality affect serum K+?

Answer 36

Elevated plasma osmolality or hypertonicity can happen in hypernatremia or hyperglycemia. Hypertonic ECF will cause movement of ICF water to ECF. When water moves out of cell, it drags K out along with it as the intracellular to extracellular conc gradient increases– which is known as solvent drag.

Question 37

What are some situations that might lead to increases plasma tonicity due to hyperglycemia?

Answer 37

This happens in diabetic ketoacidosis or diabetic hyperosmolar state, where ECF tonicity is increased due to elevated glucose concentration.

Question 38

What other thing could lead to hyperkalemia?

Answer 38

cell lysis. This usually happens when there is Rhabdomyolysis or hemolysisNOTE: The opposite thing can happen during rapid cellular proliferation such as in case of malignancy: extracelluar K is taken up rapidly by proliferating cells, which lead to fall in ECF K+

Question 39

What is hyperkalemia defined as?

Answer 39

serum K above 5.5 in ECF

Question 40

What are the three broad types of hyperkalemia?

Answer 40

-too much K with our diet, -K excretion impairment -balance between ICF and ECF is altered with release of K from ICF.

Question 41

In patients with normal function it is very unlikely to increase serum K level by po or IV intake. Why?

Answer 41

Because normal kidney is very efficient in removing extra K. So hyperkalemia most commonly happens in patients who have some degree of renal failure.

Question 42

What are the EKG manifestations of increased K+?

Answer 42

tall, peaked T wave at slightly elevated K+ levels followed by: -widening of the QRS complex, -prolonged PR inerval, -loss of p wave, -further widening of QRS complex. And ultimately sine wave which indicate ventricular tachycardia (at very high conc of K+).

Question 43

What is the main complication of hyperkalemia?

Answer 43

cardiac toxicity. It can present as EKG changes that we just discussed, it can also cause defects in cardiac impulse conduction, and arrhythmias. Similar effect on skeletal and smooth muscle can cause weakness, paralysis.

Question 44

T or F. The arrhythmias that are associated associated with hyperkalemia is Bradyarryhthmias.

Answer 44

T. Why?

Question 45

How is hyperkalemia treated?

Answer 45

-IV calcium to stablize cardiac muscle cells if needed (onset in 1-3 minutes and duration is 30-60 min)- Lower serum K+ with insulin, B2 agonists, HCO3- to promote cellular uptake- Lower serum K+ with diuretics, dialysis, or cation exchange resin (kayexalate) to move K+ outside the body

Question 46

How does kayexalate work?

Answer 46

can excrete K+ in stool (onset in 2-3 hrs and acts for about 4-6 hrs)

Question 47

Which drug that promotes increased cellular K+ uptake acts longest? Which has the earliest onset?

Answer 47

insulin (onset-30 min; duration 4-6 hrs)HCO3- (onset-15 min; duration 1-2hrs)Albuterol (onset-30 min; duration 2-4hrs)

Question 48

Onset and duration of furosemide

Answer 48

onset-5 minduration- 2hrs

Question 49

What is hypokalemia defined as?

Answer 49

less than 3.5

Question 50

What are the three broad causes of hypokalemia?

Answer 50

-dietary deficient of K, -increased K excretion, -if the balance between ICF and ECF is altered with movement of K from ECF to ICF.

Question 51

T or F. Cutaneous loss is rarely a cause for hypokalemia.

Answer 51

T.

Question 52

What are normotensive hypokalemic disorders?

Answer 52

excessive renal loss of K+ with normal BP

Question 53

Normotensive hypokalemia can be associated with metabolic alkalosis or metabolic acidosis. What are some cause of NH associated with metabolic alkalosis (high HCO3-)??

Answer 53

diuretics, vomiting, and Bartter’s and Gitelman’s syndrome

Question 54

What are some cause of NH associated with metabolic acidosis (low HCO3-)?

Answer 54

• renal tubular acidosis, which are a group of disorders where there is dysfunction of renal tubules that cause low serum potassium and acidosis- In ureteral diversion surgery, ureters are detached from the urinary bladder and attached to ileum where it is known Uretero-ileostomy or to the sigmoid colon where it is known as uretero-sigmoidostomy. In both cases colon losses HCO3 and reabsorbs NH4Cl.

Question 55

There are 3 different types RTA. Which types are associated with hypokalemia?

Answer 55

Type 2 and 1 RTA are associated with hypokalemia.

Question 56

What is the main site for K+ reabsorption?

Answer 56

PT

Question 57

Dysfunction in proximal tubule can cause ____ where there is impairment in HCO3 absorption as well as K reabsorption

Answer 57

type 2 RTA

Question 58

How do Furosemide and Bartter’s syndrome cause hypokalemia?

Answer 58

In TALH diuretics Furosemide and Bartter’s syndrome can cause problem with NaK2Cl co-transporter which will impair Na reabsorptionThis will result in increased Na delivery to the CD and increased K lossSimilar thing happens in the distal tubule with diuretics Thiazide and Gitleman’s syndrome which cause problem with Na transporters.

Question 59

What causes RTA type 1?

Answer 59

Dysfunction of the collecting duct

Question 60

How does persistent vomiting cause hypokalemia?

Answer 60

Vomiting will cause loss of fluid and H and Cl. Loss of fluid and inability to intake will decrease ECF volume, hypotension and release of hormone Aldosterone. Normally in distal tubule Na and Cl get reabsorbed together that maintain electroneutality of the tubule. So when Cl is lost, there will be less Cl delivered to the distal tubule. Instead Na will be delivered to distal tubule with negatively charged HCO3. At the same time elevated aldosterone in collecting tubule will cause reabsorption of Na which will increase electro negativity of the lumen resulting increased secretion of K and H. So you can find hypokalemia, metabolic alkalosis in blood but aciduria in urine, that is why the term paradoxical aciduria.

Question 61

Is vomiting associated with metabolic alkalosis or acidosis?

Answer 61

Loss of H will result in elevated HCO3 level in blood or metabolic alkalosis.

Question 62

Hypertensive disorders with hypokalemia are usually due to what?

Answer 62

increased activity of the aldosterone. It can be due to primary hyperaldosteronism associated with adrenal gland tumor or adrenal hyperplasia, or it can be secondary to elevated renin secretion from renin secretion tumor or renal artery stenosis. In both cases hypokalemia occurred due to stimulation of aldosterone

Question 63

Are there any other causes of hypertensive disorders with hypokalemia?

Answer 63

Yes, can be caused by glucocorticoid release

Question 64

What can glucocorticoids do?

Answer 64

Glucorticoids can stimulate the aldosterone receptors in the distal tubular cells, although not as strongly as aldosterone (causing a small degree of hypokalemia). Among them most common that you are going to see is the exogenous steroid, where patient will be receiving high dose oral or IV streroid in the form of prednisone or hydrocortisone. This is common in the setting of Rx for patients with transplantaion, autoimmune disease, obstructive pulmonary disease.

Question 65

Like hyperkalemia, hypokalemia is also characterized by some specific changes in EKG.

Answer 65

-flat T waves-U wave formation after t waves-ST deprsssion with severe hypokalemia.

Question 66

What symptoms are associated with chronic hypokalemia?

Answer 66

Most are asymtomatic. Sx varies with organ systems.However, its effect is most pronounced on muscles where is K+ is need for neuromuscular transmission (producing weakness and rhabdomyolysis)

Question 67

The arrythmias associated with hypokalemia are _____.

Answer 67

tachyarrythmias

Question 68

Other symptoms of chronic hypokalemia?

Answer 68

-elevated BP (HTN). -ADH resistance and lead to nephrogenic DI.

Question 69

What is the treatment for hypokalemia?

Answer 69

K replacement except in very very rare cases where there is massive intracellular shift of K. K supplement is usually given as KCl or KPO4 if there is concomitant PO4 deficiency.

Question 70

How can you estimate how much K+ is needed?

Answer 70

Because K is an intracellular lyte, extracellular K level or serum K level only gives us approximate deficiency of total body K. Usually it is estimated loss of 200 to 400 meq total body K will result in drop of serum K from 4 to 3.

Question 71

How should K+ be infused?

Answer 71

IV. K should be given slowly 10 meq over 2 hrs. Rapid infusion of K can cause cardiac arrest.

Question 72

What is another treatment option for hypokalemia?

Answer 72

K+ sparing diuretics. This is usually used in cases of chronic hyopokalemia.

Question 73

What are the types of K sparing diuretics?

Answer 73

2 different types, both of which work on the collecting tubule and decrease K secretion. 1. Aldosterone receptor antagonists: Which act by preventing the binding of aldosterone with the aldosterone receptors. 2. ENa channel inhibitors (amiloride, Triamterene) These act inhibiting the ENa channel Inhibiting this channel will increase the +ve charges in the lumen, which in turn will prevent K secretion.

Question 74

What level of GFR forces patients to maintain a low K+ diet? Why?

Answer 74

30 ml/min because the kidney cannot effectively secrete it