All of the following are true about potassium, except

Leaves the cell in the presence of insulin

Mostly concentrated inside the cells

Plasma concentration increases at time of metabolic acidosis

Ingestion of acetazolamide results in potassium loss

Where does potassium reabsorption primarily occur in the kidney?

Limited to the descending limb of Henle

In the collecting duct through secretion

Which of the following is not an effect of efferent arteriole constriction:

Increased glomerular hydrostatic pressure

Decreased blood flow in peritubular vessels

Increased oncotic pressure in peritubular vessels

Assertion: RMP depends on proteins and phosphate ions. Reason: Diffusion potential can be calculated using nernst equation. Choose the best statement regarding the assertion and reason.

Both true, Reason is not the explanation of assertion

Both true, Reason is the explanation of assertion

Potassium Regulation for UPSC-CMS: High-Yield Physiology Lessons

K+ Fundamentals - Body's Electric Current

Major intracellular cation. Sets Resting Membrane Potential (RMP), crucial for nerve/muscle function (body's "electric current").
RMP primarily determined by the $ [K^+]_i/[K^+]_e $ ratio.
Normal serum K+: 3.5-5.0 mEq/L. Total body K+: ~50-55 mEq/kg.
Distribution:
- ICF: ~~98% (~~140 mEq/L)
- ECF: ~~2% (~~4 mEq/L)
Na+/K+ ATPase pump actively maintains this steep gradient.

⭐ Minor ECF K+ shifts can cause life-threatening cardiac arrhythmias and muscle weakness due to significant RMP changes.

Renal K+ Transport - Nephron's Masterclass

Kidneys excrete ~90-95% dietary K+, primarily via distal nephron regulation.

Proximal Convoluted Tubule (PCT)
- Reabsorbs ~65-70% K+.
- Mainly paracellular (solvent drag).
Thick Ascending Limb (TAL)
- Reabsorbs ~20-25% K+.
- Apical NKCC2 (Na-K-2Cl cotransporter).
- Paracellular.
Distal Nephron (DCT & Collecting Ducts - CD): Fine-tunes K+ excretion.
- Principal Cells: K+ secretion.
  - Apical: ROMK, BK channels.
  - Basolateral: Na+/K+ ATPase.
  - Aldosterone: ↑ K+ secretion (↑ENaC, ↑Na/K ATPase, ↑ROMK).
  - High flow rate: ↑ K+ secretion.
- α-Intercalated Cells: K+ reabsorption.
  - Apical H+/K+ ATPase (active in K+ depletion).

K+ transport in nephron under different dietary intake

Key Regulators of Distal K+ Secretion:

Aldosterone: ↑ secretion.
Plasma [K+]: ↑[K+] stimulates aldosterone & directly ↑ secretion.
Tubular flow rate: ↑ flow ↑ secretion.
Acid-base: Alkalosis ↑ secretion; Acidosis ↓ secretion.

⭐ Exam Favourite: Loop and Thiazide diuretics cause hypokalemia by increasing distal K+ secretion (due to ↑ flow & Na+ delivery).

Flowchart: K+ Handling in Principal Cell

K+ Homeostasis Factors - The Control Knobs

I. Internal Balance (Transcellular K+ Shifts):

Insulin & β2-Agonists (e.g., Adrenaline): Drive K+ INTO cells, ↓ plasma K+.
- Mechanism: Stimulate Na+/K+-ATPase.
Acid-Base Balance: Acidemia (esp. inorganic) shifts K+ OUT (↑ plasma K+); Alkalemia shifts K+ IN (↓ plasma K+).
- 📌 Mnemonic: "Al-K+-low-sis" (Alkalosis, K+ low in plasma).
Plasma Osmolality: Hyperosmolality draws K+ OUT of cells (solvent drag), ↑ plasma K+.
Cell Lysis (e.g., Rhabdomyolysis): Releases intracellular K+, ↑ plasma K+.

II. External Balance (Renal K+ Excretion - Principal Cells in Late DCT & CD):

Aldosterone: Potently ↑ K+ secretion.
- Actions: Upregulates Na+/K+-ATPase (basolateral), ENaC & ROMK channels (apical).
Plasma [K+] Level: High plasma K+ directly ↑ K+ secretion & stimulates aldosterone release.
Distal Tubular Flow & Na+ Delivery: ↑ Flow/Na+ (e.g., loop/thiazide diuretics) enhances K+ secretion.
ADH (Vasopressin): Can ↑ K+ secretion (e.g., by ↑ ROMK activity).

⭐ Hyperkalemia is a potent, direct stimulator of aldosterone secretion from the adrenal cortex, independent of RAAS.

Potassium distribution and excretion

High‑Yield Points - ⚡ Biggest Takeaways

Principal cells (late DCT/CD) are key for K+ secretion, driven by aldosterone and plasma K+.

Type A intercalated cells mediate K+ reabsorption using H+/K+ ATPase.

Aldosterone boosts K+ secretion by upregulating Na+/K+ ATPase, ENaC, and K+ channels.

Acidosis (acute) ↓ K+ secretion; Alkalosis (acute) ↑ K+ secretion.

Insulin and β-adrenergic agonists shift K+ intracellularly, reducing plasma K+.

Loop and thiazide diuretics ↑ K+ loss; K+-sparing diuretics conserve K+.

Renal failure (↓ GFR) is a major risk factor for hyperkalemia.

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