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Diuretics1) the role of different portions
of the nephron in ion exchange;
2) the sites of action and pharmacology of diuretics;
3) the therapeutic applications of diuretics
A diuretic -
is any drug that elevates the rate of bodily urine excretion (diuresis).
All diuretics increase the excretion of water from the body.
Classification /due to location of action/
1. Diuretics which increase glomerular filtration rate
/Xanthines/Caffeine, TheophyllinumEuphyllinum
2. Proximal convoluted tubule diuretics
2.1. Osmotic diuretic Mannitol
2.2. Carbonic anhydrase (CA) inhibitors
Diacarbum (acetazolamide)
3. Loop (of Henle) diureticsFurosemidum BumetanidumEthacrynic acid
4. Distal convoluted tubule diuretics/Thiazides and thiazide-like drugs/ Hydrochlorothiazidum
5. Collecting duct diuretics5.1. Antagonist of aldosterone
Spironolactonum
5.2. Agents inhibit the Na+ channel in the apical membrane
AmiloridumTriamterenum
Indications:
Hypertension CHF, Nephrotic syndrome Poisonings
Proximal convoluted tubule diuretics
The proximal tubule (PT) determines the rate of Na+ and H2O delivery to the more distal portions of the nephron
A wide variety of transporters couple Na+ movement into the cell to the movement of amino acids, glucose, phosphate, and other solutes
MannitolMechanism of Action
o Mannitol is a non-metabolizable osmotic diuretic and is filtered into the tubular space where it markedly increases tubular fluid osmolality.
o This results in impared reabsorption of fluid with a resultant increased excretion of water (some Na+ accompanies)
Pharmacokinetics of Mannitol:
o Given only i.v. and acts within 10 min; o if given p.o. it causes an osmotic diarrhea
(not well absorbed from gut). o In pts with normal renal function t1/2 is
approx. 1.2 hr.
Indications:
prophylaxis against renal dysfunction, e.g. major surgical procedure
Contraindications: CHF, chronic renal failure
Carbonic anhydrase (CA) inhibitors
Carbonic anhydrase (CA) inhibitors Mechanism of Action:
If CA activity is inhibited, HCO3- reabsorption is reduced and exits the proximal tubule in much larger amounts.
In the distal nephron, Na+ is largely reabsorbed (unlike HCO3-) and is exchanged for K+. Therefore acetazolamide primarily causes an increase in urinary HCO3-, K+, and water excretion.
CA Inhibitors: Adverse Side Effects hypokalemia metabolic acidosis
Loop Diuretics
Loop Diuretics: Mechanism of Action block the Na+/K+/Cl- co-transporter in
the apical membrane of the thick ascending limb of Henle's loop. Therefore, loop diuretics increase urinary water, ions excretion.
cause dilation of the venous system and renal vasodilation - effects that may be mediated by prostaglandins.
Loop diuretics: Pharmacokinetics - act within 20 min and t1/2 is approx. 1-
1.5 hr. - are rapidly absorbed from the gut and
can be given i.v. - are the most potent available and can
cause excretion of up to 20% of the filtered Na+.
Clinical uses of loop diuretics acute pulmonary oedema chronic heart failure cirrhosis of the liver complicated by
ascites nephrotic syndrome renal failure.
Loop diuretics Adverse Side Effects hypokalemia metabolic alkalosis hypomagnesemia hyperuricemia dehydration (hypovolemia), leading to
hypotension dose-related hearing loss (ototoxicity)
Thiazides: Mechanism of Action They inhibit Na+ and Cl- transport in the
cortical thick ascending limb and early distal tubule.
They have a milder diuretic action than do the loop diuretics because this nephron site reabsorbs less Na+ than the thick ascending limb.
Thiazides
Thiazides: Pharmacokinetics
All are well absorbed from the gut. Onset of action is within approx. 1 hr;
effects can be long lasting but vary with the drug used (6-48 hr).
Clinical uses of thiazide diuretics Hypertension. Mild heart failure (loop diuretics are
usually preferred). Severe resistant oedema (together
with loop diuretics).
Thiazides have a week antihypertensive
effect because reduce arterial wall sensitivityto NA (noradrenaline) and AT (Angiotensin).
They potentiate significantly the effectof other antihypertensive drugs.
Thiazide Adverse Side Effects hypokalemia metabolic alkalosis dehydration (hypovolemia), leading to
hypotension hyponatremia hyperglycemia in diabetics hyperuricemia (at low doses) Erectile dysfunction
Potassium sparing diuretics
These agents are often given to avoid the hypokalemia
They should never be given in the setting of hyperkalemia (diabetes mellitus, multiple myeloma, renal insufficiency)
SpironolactoneMechanism of Action
It is a competitive antagonist of aldosterone. Therefore it blocks aldosterone-stimulated Na+ reabsorption and K+ and H+ excretion in the late distal tubule and collecting duct.
Potassium sparing diuretics
SpironolactonePharmacokinetics: Given orally, spironolactone takes
up to 2 days to be effective with a t1/2 approx. 20 hr.
Amiloride and triamtereneMechanism of Action inhibit the Na+ channel in the apical
membrane of the late distal tubule and collecting duct.
Because K+ and H+ secretion in this nephron segment are driven by the electrochemical gradient generated by Na+ reabsorption, K+ and H+ transport into the urine is reduced.
Clinical uses of potassium-sparing diuretics (e.g. amiloride, spironolactone) in heart failure, where either of these
improves survival in primary hyperaldosteronism (Conn's
syndrome) in resistant essential hypertension
(especially low-renin hypertension) in secondary hyperaldosteronism caused
by hepatic cirrhosis complicated by ascites.
K+-sparing diuretics Adverse Side Effects hyperkalemia metabolic acidosis gynecomastia (aldosterone antagonists) gastric problems including peptic ulcer
Arctostaphylos uva-ursi L. (Bearberry)
Stipites Cerasorum(Cherry)
Equisetum arvense(Common horsetail)
Containssilicates with diureticand urolitholytic effects.