Thiazides and related agents

They are developed in efforts to develop more potent carbonic anhydrase inhibitors. So, that is why they are structurally similar to the carbonic anhydrase inhibitors.

Mechanism of action:
1. They cause the inhibition of Na+/Cl- cotransporter reabsorption from luminal side of epithelial cells in
    a. early distal convoluted tubule and also
    b. in late proximal tubule but not to a lesser degree.

This causes an increase in the concentration of NaCl in the tubular fluid resulting in urinary excretion of sodium and water.
2. They also cause an increase in Ca2+ reabsorption in distal convoluted tubule that may be due to lowering of cell Na+.
3. They also increase excretion of chloride, potassium and to some extent bicarbonate ions.

The excretion of Na+ and Cl- result in a very hyperosmolar urine.

4. They also directly relax arteriolar smooth muscle and cause a decrease in peripheral vascular resistance, resulting in continued hypotensive effect.

The hypotensive effect is also attributed to the decreased sodium level and as a result in the reduction of plasma volume which leads to decreased cardiac output.

5. They also decrease glomerular filtration rate.
Thiazide diuretics interfere with the dilution of the urine but not with the concentration of the urine due to the site of action.

Therapeutic uses:
1. Mild to moderate cases of Hypertension:
Three to seven days of continued treatment leads to lower peripheral resistance resulting in the stabilization of blood pressure.

2. Congestive cardiac failure:
They have the ability of reducing plasma volume helping in mild to moderate heart failure.

3. Diabetic nephropathy

4. Edema which may be due to congestive heart failure, renal dysfunction or corticosteroid therapy

5. Nephrosis

6. Prevent the formation of calcium stones in hypercalciuric and normal calciuric patients. As thiazide diuretics have the ability of inhibiting urinary Ca2+ excretion

Pharmacokinetics:
They are effective orally. There half life is about 35-42 hours. They are excreted by the kidney by organic acid secretary system of proximal tubule.

Adverse effects:
1. Gastrointestinal
Gastric irritation, anorexia, nausea, vomiting, diarrhea, constipation

2. Central nervous system
Weakness, fatigability, dizziness, vertigo, headache

3. Hematological
Leukopenia, agronulocytosis, aplsatic anemia

4. Cardiovascular
Orthostatic hypotension can be caused by volume depletion.

5. Hypersensitivity
Generalized dermatitis, hemolytic anemia, photosensitivity, rash, purpura

6. Hypercalcemia

7. Hypokalemia
Decreased intravascular volume activates rennin angiotensin aldosterone system resulting in K+ loss with urine.

This potassium loss can be decreased by spironolactone which interferes with aldosterone action or by giving triamterene. This can also be done by in creasing the intake of citrus fruits and bananas which are rich in potassium.


8. Hyponatremia:
This can be decreased by less water intake and decreasing the dose of thiazide diuretics.


9. Muscle spasm.

10. Hyperglycemia:
This may be due to impaired release of insulin and the uptake of glucose by the tissues.

11. Hyperuricemia:
Thiazide diuretics decrease the amount of acid excretion from the organic acid excretory system resulting in increased uric acid in the serum. This results in the gouty attacks.

Contraindications:
It is contraindicated in patients who are hypersensitive to thiazide or sulfonamides. It is also contraindicated in anuria, healthy pregnant women and hepatic cirrhosis.

Precautions:
It should be used with caution in patients of renal disease, gout or diabetes. In patients of renal disease it may initiate azotemia.

Drug Interaction:

Classification of Diuretics

Classification according to different groups:

Antidiuretic (ADH) hormone antagonists:
Lithium salts, demeclocycline, conivaptan

Carbonic anhydrase inhibitors:
Acetazolamide, Acetazolamide sodium

Loop (High ceiling) diuretics:
Bumetanide, Ethacrynic acid, Ethacrynate sodium, Furosemide, Torsemide, Umetanide, Piretanide

Mercurial diuretics:
Mercaptomerin, Calomel, Mercuhydrin, Meralluride, Mercumatilin, Mersalyl

Methylxanthine diuretics:
Aminophylline, Theobromine, caffeine, Theophylline, Oxtriphylline (A salt of theophylline)

Osmotic diuretics:
1. Osmotic electrolytes:
Sodium and potassium salts

2. Osmotic non-electrolytes:
Mannitol, Urea, Isosorbide, Sucrose, Glycerin

3. Acid-forming salts:
Ammonium chloride

Plant products:
Taraxacum, Cornsilk, Allium (Syn. Garlic), Buchu (dried leaves of Barosma betulina), Oleander, Turpentine oil

Potassium sparing diuretics:
Amiloride hydrochloride, Triamterene

Aldosterone antagonist:
Spironolactone, Aldadiene (A metabolite of apironolactone)

Thiazide diuretics:
Buthiazide, Chlorothiazide, Chlorthalidone, Hydrochlorothiazide, Indapamide, Metolazone, Cyclothiazide

Uracil derivatives:
Aminometramide

Miscellaneous diuretics:
Dextran, Ammonium benzoate, Dimethylpiperazine tartarate

Classification according to site of action:

Direct diuretics
1. Drugs acting on proximal tubule
Osmotic diuretics, Carbonic anhydrase inhibitors, Methylxanthine diuretics

2. Drugs acting on ascending limb of loop of henle
Loop (high ceiling) diuretics, Mercurial diuretics

3. Drugs acting on distal tubule
Thiazide diuretics

4. Drugs acting on collecting tubule
Potassium sparing diuretics, ADH antagonists, Aldosterone antagonists

Indirect diuretics
Cardiac diuretics

Diuretics

Introduction:

Diuretics are the drugs that cause the increased outflow of urine.

General action of diuretics:
Many types of diuretics
1. Decrease that amount of fluid which is reabsorbed by the renal tubules, from where the fluid returns to the blood
2. Increase glomerular filtration

General uses of diuretics:
They are used to remove excess water from the body which may contain some salts, toxins and other accumulated waste products such as urea.

They have the ability of getting rid of excess fluid from the body which may cause edema, which contains an abnormal accumulation of fluid from serum resulting in some of the disease.

Aprotinin

It is inhibitor of proteolytic enzymes.


It causes blockage of plasmin resulting in stoppage of bleeding.

It can cause inhibition of streptokinase.

It is used prophylactically for reducing blood loss around the time of operation. It is also used for hyperplasminaemia developed as a result of fibrinolytic drug overdosage.

It may start certain inflammatory conditions.

Vitamin K

It can be used for oral anti-coagulants.

Mechanism of action:
It causes post-translational modification of factors VII, IX and X.

Therapeutic uses:
It is usually administered to all newborn babies in order to prevent vitamin K deficiency leading to hemorrhagic diseases which is common in premature infants.

It is also used as an antidote of warfarin.

Adverse effects:
Rapid infusion of vitamin K may lead to chest pain, back pain and dyspnea.

Protamine sulfate

It is an antidote for heparin.

It is obtained from fish sperm.

It is strongly basic macromolecule due to the presence of more amount of arginine.

In this positive charge of protamine forms complex with negative charge of heparin (a polyanionic macromolecule) neutralizing its activity.

It is administered IV after proper dilution with physiological salt solution. Its duration of affect is 2 hours.

Hypersensitivity reactions may develop. On rapid injection, flushing, dyspnea, hypotension, and bradycardia may be caused.

Aminocaproic acid and Tranexamic acid

These are synthetic inhibitors of plasminogen activator with antiplasmin activity.

These are active orally and excreted in urine. Tranexamic acid can cross placenta.

Therapeutic uses:
Aminocaproic acid is effective in the treatment of complications caused by fibrinolysis such as in the treatment of cardiac bypass or major thoracic surgery. It is also found useful in the treatment of subarachnoid hemorrhage and angioedema.

The most important use of tranexamic acid is in the treatment of ovarian tumor which is malignant.

Adverse effects:
They may cause IV thrombosis.

Aminocaproic acid may cause rash, erythema, nausea, diarrhea and heartburn. It also some of the antiadrenergic effects leading to hypotension and nasal stuffiness.

Dosage:
Tranexamic acid is administered as 15mg/kg orallyas a loading dose then 30 mg/kg four times a day.