Regional Transport Flashcards
Impact of cathecolamines and angiotensin II on Na reabsorption
⬆️ fraction of Na reabsorbed in PT
*(+) baso lateral Na/K ATPase
How is the absorption of HCO3 in a volume depleted state? Why?
- ⬆️ HCO3 reabsorption in PT
- ⬆️ Ag II (+) Na-H antiporter
Principal factor that control H+ secretion from PT cell and thus HCO3 reabsorption. How are they at acidosis and alkalosis state?
- [H+] in the cell
- ⬆️ both in acidosis and ⬇️ both in alkalosis
What would happen if you block carbonic anhydrase (azetazolamide) in PT? What condition could result?
- ⬇️ HCO3 reabsorption and activity of Na-H antiporter
- type II Renal Tubular Acidosis
Common causes of contraction alkalosis (metabolic alkalosis). Mechanism of production of it.
- low volume state: sweating in desert, vomiting, thiazide diuretic
- ⬆️ Ag II ▶️ ⬆️ HCO3 reabsorption
Why diarrhea doesn’t cause contraction alkalosis, although it promotes a low volume state?
Lose HCO3 in stools ▶️ metabolic acidosis
Why in Fanconi syndrome the chloride doesn’t follow the loss of Na, K and H2O? How is the complete metabolic condition?
- curiously the Cl reabsorption ⬆️ ▶️ maintain neutrality ▶️ no anion gap
- metabolic acidosis hypokalemic hyperchloremic
Why does the inulin concentration increase along the nephron? Where is the lower and higher inulin concentration?
- 2/3 water reabsorption in PT ▶️ [inulin] triple, continue ⬆️ in rest tubule system (assuming ADH acts)
- lower: bowman’s space, higher: terminal collecting duct
Function of the descending limb of loop of henle
Reabsorb 15% of filtered water
Treatment of hyponatremia, low serum osmolality and high urine osmolality in SIADH
- fluid restriction
- loop diuretic ▶️ ⬆️ plasma Na
*loop diuretic ▶️ ⬇️ reabsorption of NaCl at loop of henle ▶️ remove the concentrating function of it ▶️ ⬇️ osmolar gradient ▶️ ⬇️ reabsorption of free water from collecting duct (“fluid restriction like”)
Why Bartter’s syndrome leads secondary hiperaldosteronism? Some features of it.
- Presents a low volume state ▶️ ⬆️ renin and aldosterone
- hypokalemia, high urine Ca (low positive luminal potential), alkalosis
*genetic mutation of Na/K/2Cl transporter of loop of henle ▶️ dysfunction
Cause of familial hypocalciuric hypercalcemia (FHH)
Calcium-sensing receptor (CaSR) autosomal dominant mutation
*as also present in parathyroid gland ▶️ ⬆️ PTH (not sense ⬆️ Ca)
What is Gitelman’s syndrome and some of its features
- mutation (dysfunction) NaCl transporter of distal tubule
- hyookalemia, alkalosis, low urine Ca (difference with alteration of Na-K-2Cl transporter of loop of henle)
Acid-base disturbance in case of excess of Aldosterone
Metabolic alkalosis
How can the potassium sparing diuretics work?
- block ENac (amiloride)
- block aldosterone receptor (spironolactone)
- block production aldosterone (RAAS system blocker)
*more specific: splerenone (less side effects)
