Diuretics PDF

Summary

This document provides a detailed overview of diuretics, including their uses, classification, and characteristics. It covers various types of diuretics and their mechanisms of action. The information is relevant to medical and pharmacology students and professionals.

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DIURETICS
Diuretics are drugs that promote the output of urine excreted by the Kidneys. The primary action
of most diuretics is the direct inhibition of Na+ transport at one or more of the four major
anatomical sites along the nephron, where Na+ reabsorption takes place. The increased excretion
of water and electrolytes by the kidneys is dependent on three different processes viz.,
glomerular filtration, tubular reabsorption (active and passive) and tubular secretion.

Diuretics are very effective in the treatment of Cardiac oedema, specifically the one
related with congestive heart failure. They are employed extensively in various types of
disorders, for example, nephritic syndrome, diabetes insipidus, nutritional oedema, cirrhosis of
the liver, hypertension, oedema of pregnancy and also to lower intraocular and cerebrospinal
fluid pressure.

Therapeutic Uses of Diuretics

i) Congestive Heart Failure: The choice of the diuretic would depend on the severity of
the disorder. In an emergency like acute pulmonary oedema, intravenous Furosemide or Sodium
ethacrynate may be given. In less severe cases. Hydrochlorothiazide or Chlorthalidone may be
used. Potassium-sparing diuretics like Spironolactone or Triamterene may be added to thiazide
therapy.

ii) Essential hypertension: The thiazides usually sever as primary antihypertensive
agents. They may be used as sole agents in patients with mild hypertension or combined with
other antihypertensives in more severe cases.
 iii) Hepatic cirrhosis: Potassium-sparing diuretics like Spironolactone may be
employed. If Spironolactone alone fails, then a thiazide diuretic can be added cautiously.
Furosemide or Ethacrymnic acid may have to be used if the oedema is regractory, together with
spironolactone to lessen potassium loss. Serum potassium levels should be monitored
periodically.

iv) Nephroic syndrome: Doetary sodium restriction may be combined with a
thioazide diuretic, adding Spironolactone to control secondary hyperaldosteronism

CLASSIFICATION

Diuretics may be classified as follows.

i) Thiazides (Benzothiazides): eg. Chlorthiazide, Hydrochlorthiazide,
Hydroflumethiazide, Bendroflumethiazide,
Benzthiazide, Cyclothiazide, Cyclopenthiazide,
Methyclothiazide,Trichlormethiazide, Polythiazide.

ii) Carbonic – Anhydrase inhibitors: eg. Acetazolamide, Methazolamide,
Ethoxzolamide, Diclofenamide,
Disulfamide.

iii) Sulphonamide diuretics: eg. Quinethazone, Chlortalidone, Metolozone,
Indapamide, Clopamide, Xipamide.

iv) Aldosterone inhibitors: eg. Spiranolactone, Metyrapone, Eplerenon.

v) Angiotensin antagonist: eg. Lasartan.

vi) Loop (or) High – ceiling diuretics: eg. Burmetanide, Furosemide,
Ethacrynic acid.

vii) Pyrazinoyl guanidines: eg. Amiloride hydrochloride.

viii) Miscellaneous diuretics: eg. Triamterene, Muzolimine.

2.1. THIAZIDE AND HYDROTHIAZIDE DIURETICS

Thiazides are having the following general chemical formula.
 Thiazide and Hydrothiazide Diuretics
R N
5 4
3C R1
6
7 2 NH
8 1
H2NO2S S

O O

Thlazide Diuretics

Generic Name R R1

Chlorthiazide - Cl -H

Benzthiazide - Cl
CH2 - S - CH2

Hydrochlorthiazide (Hydride, Thiazide)

O O
H2NO2S S
NH

Cl N
H
6 - Chloro - 3, 4 - dihydro - 2H -1, 2, 4 - benzothiadiazin
- 7 - sulphonamid - 1,1 - dioxide.

CARBONIC ANHYDRASE INHIBITORS

Carbonic anhydrase inhibitors are derived from sulphonamide antibacterial.
Acetazolamide is the proto-type carbonic anhydrase inhibitor.

This type of diuretics inhibit carbonic anhydrase enzyme in the membrane and cytoplasm
of the epithelial cell. Carbonic anhydrase influence tubular reabsorption of sodium at two sites:
in the proximal tubule where bicarbonate absorption occurs and in the distal tubule where
sodium is exchanged for potassuim or hydrogen ion and bicarbonate is formed as an
accompanying anion.

The hydration of CO2 takes place under the influence of carbonic anhydrase to form
carbonic acid which dissociates to give hydrogen and bicarbonate ion.
 Carbonic
CO2 + H2 H2CO3 H+ + HCO3-
anhydrase

In relation to the tubular cell, carbonic anhydrase helps to produce H+ ion, which are
secreted into the tubules in exchange for Na+ ion. The sodium-hydrogen ion exchange takes
place almost all along the length of the renal tubule and normally is responsible for the formation
of acid urine, while conserving the stores of bicarbonate along with sodium.

Carbonic anhydrase inhibitors act by blocking the enzyme, while prevents the
reabsorption of HCO3-. Accumulation of HCO3- in the tubules inhibits Na+ - H+ exchange and
Na+ reabsorption.

The sodium is eliminated along with bicarbonate ions and the water in which they are
dissolved. The urine becomes alkaline the increase in Na+ concentration in the tubular fluid may
be compensated partially by increased NaCl reabsorption in later segment of the tubule. Thus the
diuretic effect of the carbonic anhydrase inhibitors in mild.

These agents decrease the activity of carbonic anhydrase at other sites in the body like the
CNS, the eye, the lungs and the gastrointestinal tract.

Acetazolamide (Acetamide, Avva)

N N
O

H3C.CHN S SO2NH2

N - (5 - Sulfamoyl - 1,3,4 - thiadiazol - 2
- yl) acetamide.

SULPHONAMIDE DIURETICS
The actions of these drugs are very similar to the thiazide diuretics, except that these
specifically possess longer duration of action.

O O O O O
O

H2N - S S H2N - S C
1 N R1 N R1
2
O R2 O R2
3
4 H
6 H
R3 N R3 N
5 H H
Thiazides isosteres
Benzothiadiazines
(Thiazides)
 ALDOSTERONE ANTAGONOSTS
Spiranolactone (Aldactone, Aldactide)

O

O

O SCOCH3

7 - (Acetylthio) - 17 - hydroxy - 3 - oxopregn - 4- en -
21 - carboxylic acidlactone

ADR: Fluid or electrolyte imbalance, gynaecomestia.

Dose: 25-100mg daily.

Use: It is useful in cirrhosis of liver, aldosterone - secreting tumors and high – renin
hypertension.

HIGH CEILING OR LOOP DIURERTICS

Furosemide, Bumetanide and Ethacrynic acid have been labelled as “high-ceiling” or
loop diuretic”, because they inhibit the sodium and chloride rebsorption in the thick segment of
the ascending limb of the loop of Henle as well as in the proximal convoluted tubule and the
distal diluting site. Thus they are very potent diuretics, and ionduce a dramatic and copious flow
of urine rich in sodium chloride. The loop diuretics have completely replaced the mercurials
(mersalyl). The use of organomercurials and ammonium chloride as diuretics is obsolete.

Their major action is to reduce active Cl- reabsorption in the ascending limb of the loop
of Henle. In addition, there are minor actions on Na+ reabsorption in the proximal tubule, and the
distal tubule. There is an increased urine volume with loss of Na+, K+ and Cl-. The Cl- loss
induces hypochloraemic alkalosis and K+ loss may provoke digoxin intoxication. Uric acid
secretion is reduced and this may induce gout in susceptible individuals. Unlike most other
diuretics, the loop diuretics continue to be effective even in the presence of electrolyte and acid-
base imbalance and nitrogen retention.

Furosemide and Bumetanide are sulphonamide compounds. Both of them as well as
Ethacrymic acid, contains a free carboxyl group, which helps them to be transported into a
longer segment of the tubule than the thiazides. Hence the loop diuretics inhibit sodium and
chloride reabsorption over a longer length of the nephron producing more diuresis than the
thiazides