A comprehensive presentation on Metabolism of Potassium and its clinical significance for MBBS, BDS, B Pharm & Biotechnology students to facilitate self- study.

1. Metabolism of Potassium
and its clinical significance
Dr. Rohini C Sane

4. Dietary sources of potassium
• Oranges
• Bananas
• Pine apple
• Potato
• Tender coconut
• Fresh vegetables
• chicken
• liver
Average diet provides 4 gm of potassium /day

5. Functions of Potassium (K⁺ ) in human body
 Functions of Potassium (K⁺ ) in human body
1. Major intracellular cation
2. Extracellular K⁺ influences skeletal & muscle activities (including
cardiac muscles)
3. Transmission of nerve impulse
4. Acid base balance
5. Water & electrolyte balance
6. Intracellular potassium concentration is necessary for protein
biosynthesis by ribosomes

6. Metabolism of Potassium
➢Normal serum Potassium levels : 3.5 -5.5 mequ/L
➢Daily dietary requirement : 3-4 gm /day
➢Absorption in gastrointestinal tact -90 % -efficient
➢The whole blood contains much higher levels of potassium.
(50 mequ/L ).
➢Since potassium is predominantly intracellular cation, care
should be taken to prevent hemolysis of RBC to avoid
erroneous high levels of serum potassium.(preanalytical error)

7. Homoeostasis of Potassium
❖Potassium balance or Homoeostasis is maintained by :
1. Homoeostasis of Potassium by Transcellular movement
2. Role of gastrointestinal tract in Homoeostasis of Potassium
3. Role of Kidney in Homoeostasis of Potassium

8. Homoeostasis of Potassium by Transcellular movement
❖In cells ,there is significant concentration gradient of Na + and K+ across the cell membrane.
Potassium ions exchange with hydrogen or sodium ions.
1. High intracellular concentration of potassium is maintained by an energy requiring extrusion
of 3 Na + out of the cell with replacement by K+ creating an electrochemical gradient across
the cell membrane .
2. Intracellular K + is essential for number of enzymes reactions ( such as pyruvate kinase,
protein synthesis ,and glycogen synthesis ) and for maintaining acid base balance.
3. Extracellular K+ (5 mequ/L of plasma )is important for its controlling influence
upon:
➢neuromuscular irritability
➢Cardiac muscles ( a proper balance between K+ and Ca + + is essential for contraction
of heart muscles )
➢The operation of Na + / K+ ATPase (the sodium pump )
❖Insulin stimulates the intracellular uptake of potassium.

9. Role of gastrointestinal tract in Homoeostasis of Potassium
Role of gastrointestinal tract in Homoeostasis of Potassium is as follows:
▪ Potassium from diet and gastrointestinal tract is reabsorbed in the small
intestine and secreted in colon and rectum in exchange for sodium.
▪ Small amount of Potassium (< 1 mmols/day )is excreted in the feces .
▪ In chronic diarrhea and intestinal fistula fecal excretion is
increased.

10. Potassium ions transport across the cell membrane

11. Role of Kidney in Homoeostasis of Potassium
➢Excretion of K⁺ through urine  50 -70 mequ/L (1.5-2gm/day )
➢Potassium is filtered by the glomeruli , reabsorbed in proximal convoluted
tubules (PCT) and actively secreted in distal renal tubules in exchange of
hydrogen or sodium ions.
➢If K⁺ concentration in blood rises by more than 1 mequ above normal values
(3.5-5.5meq/L )stimulation of Aldosterone secretion Aldosterone
increases secretion and excretion of K⁺ till Homoeostasis of Potassium is
established.
➢Decrease in serum /plasma K⁺ inhibit Aldosterone secretion and Aldosterone
secretion is brought about by renin –Angiotensin system of kidney.
➢Na ⁺ depletion  renin secretion by kidney* Decrease in blood volume and
pressure  triggering renin secretion  formation of Angiotensin II by the
action of renin on 2- globulin  production of Aldosterone excretion of K⁺.

12. Role of Kidney in Homoeostasis of Potassium

13. Role of Kidney in Homoeostasis of Potassium

15. Role of Kidney in Homoeostasis of Potassium
*
renin from kidney peptidase
Angiotensinogen Angiotensin I Angiotensin II
2- globulin (peptide with10 amino acids) (peptide with 8amino acids)
Angiotensin II stimulates smooth muscles and raises blood pressure
(most active vasopressor ) .It action is by constricting arterioles and
increasing heartbeats.
Angiotensin II later hydrolyzed by Angiotensinase .

17. Factors controlling Excretion of Potassium by Kidney in K⁺ Homoeostasis
❖Urinary potassium excretion depends upon:
1. Availability of sodium ions for exchange with potassium ions
2. The relative amount of hydrogen and potassium ions in the distal
tubular cells
3. Plasma Aldosterone
4. In acidosis , hydrogen ions excreted and potassium ions reabsorbed.
5. In Alkalosis potassium ions excreted and hydrogen ions reabsorbed
/conserved.

19. Homeostasis of potassium in human body

20. Homeostasis of potassium in human body

21. Clinical significance of Potassium Metabolism

22. Disorders of potassium metabolism
1. Hypokalemia: low serum potassium (deceases heartbeats and
interferes with vital muscles such as those involved in respiration)
2. Hyperkalemia : high serum potassium
The capacity of kidney to excrete potassium is so high that
Hyperkalemia will not occur normally .However it occurs in renal
failure, advanced dehydration and shock.

23. Potassium metabolism-Hypokalemia
Hypokalemia
1. serum potassium < 3mmol/ lt
2. Symptoms : muscular weakness ,cardiac arrhythmias , cardiac arrest
3. Correction by orange juice
4. K⁺ administration in beneficial effect during insulin therapy as insulin
decreases serum potassium levels
5. Alkalosis associated with influx of potassium ions in exchange of protons
6. Conditions associated with Hypokalemia
a) Renal losses
b) Prolonged vomiting
c) Diarrhea
d) Administration of Diuretics  K⁺ excretion
7. Diuretics administration should be adjuvant K⁺ supplementation

24. Causes of hypokalemia
❖Hypokalemia may occur due to :
Decreased intake of potassium
Loss of potassium from gut
Increased urinary excretion
Redistribution from ECF to ICF : after insulin treatment

25. Causes of hypokalemia-1
❖Hypokalemia may occur due to :
Decreased intake of
potassium as in
a)Dietary insufficiency
of potassium (rare 
b)Starvation
c)Severe illness
d)Post operatively
after
gastrointestinal
surgery
e)Kwashiorkor
Loss of potassium
from gut as in
a)Prolonged vomiting
b)Diarrhea
c)Steatorrhea
d)Intestinal fistula
Redistribution of
potassium from ECF
to ICF
a)after insulin
treatment
b)in alkalosis ,where
potassium enters
cells is associated
with increased
urinary loss of K+

26. Causes of hypokalemia-2
❖Hypokalemia may occur due to Increased urinary excretion :
Increased urinary excretion observed in:
✓Hyperaldosteronism
✓ Cushing’s syndrome
✓Fanconi syndrome
✓Renal tubular acidosis in which there is availability of H + for exchange
with K+
✓Ectopic production of ACTH
✓Thiazide diuretics that enhances Na + - K+ exchange and potassium
excretion
✓Drugs that potentiate the action of Aldosterone ( e.g. carbenoxolone 
✓Substances with Aldosterone like activity such as tobacco and liquor ice
✓Bartter’s syndrome in which thee is increased secretion of rennin and
Aldosterone

27. Clinical Symptoms of Hypokalemia
❖Neuromuscular manifestations
• Weakness
• Lethargy
• Hypotonia
• Depression
• Cramps
❖Cardiac manifestations
➢ Arrhythmias
➢Hypotension
➢ECG changes :ST Depression, flattened T waves ,prolonged P-R intervals,
prominent U waves
❖ Renal manifestations: inability to concentrate urine ,polyuria
❖ Alkalosis

28. ECG changes :ST Depression, flattened T waves ,prolonged P-R intervals,
prominent U waves
ECG changes in Hypokalemia

29. Management of Hypokalemia
➢Management of Hypokalemia include:
➢Oral administration of potassium chloride
➢Intravenous infusion of potassium chloride if Oral administration not
possible

30. Interventions for hypokalemia based on serum potassium levels

33. Causes of Hyperkalemia-1
❖Hyperkalemia may result from :
increased intake of potassium
Decreased urinary excretion of potassium
Excessive parenteral administration for treatment of
hypokalemia
Redistribution of potassium from ICF to ECF

34. Causes of Hyperkalemia- 2
❖Hyperkalemia may result from :
Decreased urinary of
potassium excretion as in
• Addison’s disease
( adrenocortical
insufficiency)
• Congenital adrenal
hyperplasia
Redistribution of
potassium from ICF to ECF
• Severe tissue damage
• Injury ,burns ,
postoperative conditions
• Hypoxia with failure of
the sodium pump
• Acidosis associated with
urinary excretion of
potassium

35. Pathogenesis of Hyperkalemia

36. Clinical Symptoms of Hyperkalemia
❖Neuromuscular manifestations
• Decreased membrane potential
• Increased repolarization
❖Cardiac manifestations
✓Decreased cardiac action potential
✓Bradycardia
✓cardiac arrest
✓Ventricular fibrillation
➢ECG changes : High T waves ,loss of P waves, broad QRS complex

37. Clinical Symptoms of Hyperkalemia

38. Clinical Symptoms of Hyperkalemia

39. ECG changes in Hyperkalemia

40. Management of Hyperkalemia-1
• Management of Hyperkalemia include:
• Dietary control
• Correction of acidosis or water and sodium depletion
• Intravenous administration of calcium gluconate to reverse cardiac
changes
• Insulin administration to promote potassium entry into cells
Insulin induced hypoglycemia can be prevented by glucose.
• Bicarbonate infusion to promote potassium entry into cells
• Potassium binding ion exchange resins that increase potassium
excretion by exchanging sodium or calcium ions
• Dialysis to remove excess potassium

41. Management of Hyperkalemia based on its severity-2

42. Management of Hyperkalemia based on ECG changes-3

43. Comparison of hypokalemia and Hyperkalemia

44. Comparison of ECG changes in hypokalemia and Hyperkalemia