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Drugs Acting on the Renal System

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Presentation on theme: "Drugs Acting on the Renal System"— Presentation transcript:

1 Drugs Acting on the Renal System

2 I. Diuretics Introduction
Function: Diuretics increase urine production by acting on the kidney. Most agents affect water balance indirectly by altering electrolyte reabsorption or secretion. Osmotic agents affect water balance directly. Effects: Natriuretic diuretics produce diuresis, associated with increased sodium (Na+) excretion, which results in a concomitant loss of water and a reduction of extracellular volume.

3 Congestive heart failure (CHF)
Therapeutic use: Diuretic agents are generally used for the management of: Edema Hypertension Congestive heart failure (CHF) abnormalities in body fluid distribution Side effects: Diuretics can cause: electrolyte imbalances such as hypokalemia, hyponatremia, and hypochloremia disturbances in acid—base balance.

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5 Thiazide diuretics Mechanism
Thiazide diuretics are absorbed from the gastrointestinal (GI) tract and produce diuresis within 1—2 hours. They are secreted into the lumen of the proximal tubule via an organic acid carrier. They exert effects only after reaching the lumen.

6 These agents inhibit active reabsorption of sodium chloride (NaCl) in the distal convoluted tubule by interfering with NCC (Na+—Cl- cotransporter) a specific Na+/Cl- transport protein, resulting in the net excretion of Na+ and an accompanying volume of water. These agents increase excretion of Cl- Na+ K+ at high doses, HCO3- They reduce excretion of calcium (Ca 2+ ).

7 Thiazide diuretics can be derivatives of sulfonamides (sulfonamide diuretics).
Many also inhibit carbonic anhydrase, resulting in diminished bicarbonate (HCO3-) reabsorption by the proximal tubule.

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9 Specific agents Prototype drugs include: Chlorothiazide
Hydrochlorothiazide Other agents include: methyclothiazide polythiazide many others Chlorothiazide is the only thiazide available for parenteral use.

10 Thiazide-like drugs. Quinazolinones (e.g., metolazone, chlorthalidone) indolines (e.g., indapamide) have properties generally similar to those of the thiazide diuretics. Unlike thiazides, these agents may be effective in the presence of some renal impairment.

11 3. Therapeutic uses: Thiazide diuretics are the preferred class of diuretic for treatment of hypertension when renal function is normal; they are often used in combination with other antihypertensive agents to enhance their blood pressure-lowering effects. These agents reduce the formation of new calcium stones in idiopathic hypercalciuria.

12 Thiazide diuretics may be useful in patients with diabetes insipidus that is not responsive to antidiuretic hormone (ADH). These agents are often used in combination with a potassium-sparing diuretic to manage: mild cardiac edema cirrhotic or nephrotic edema edema produced by hormone imbalances Ménière's disease (a disorder of the inner ear that can affect hearing and balance.)

13 Adverse effects and contraindications
Thiazide diuretics produce electrolyte imbalances such as hypokalemia, hyponatremia, and hypochloremic alkalosis. These imbalances are often accompanied by central nervous system (CNS) disturbances, including dizziness, confusion, and irritability; muscle weakness; cardiac arrhythmias; and by decreasing plasma K+, increased sensitivity to digitalis-like drugs.

14 Half-Life (h) Potency Chemical Class Drug 2 0.1 Benzothiadiazide Chlorothiazide 3 1.0 Hydrochlorothiazide 5 Quinazoline Metolazone 26 10 Chlorthalidone 16 20 Indoline Indapamide

15 2. These agents often elevate serum urate, presumably as a result of competition for the organic acid carrier (which also eliminates uric acid). Gout-like symptoms may appear. 3. Thiazide diuretics can cause hyperglycemia, especially in patients with diabetes, and hypersensitivity reactions.

16 Loop diuretics Mechanism: absorbed by the GI tract eliminated by:
filtration tubular secretion; some elimination occurs via the hepatic—biliary route. They are administered either orally or parenterally. Diuresis occurs within: 5 minutes of intravenous (IV) administration 30 minutes of oral administration.

17 Loop diuretics inhibit active NaCl reabsorption in the thick ascending limb of the loop of Henle by inhibiting NKCC2, a specific Na+/K+/2 Cl- cotransporter. Because of the high capacity for NaCl reabsorption in this segment, agents active at this site markedly increase water and electrolyte excretion and are referred to as high-ceiling diuretics. These agents: reduce reabsorption of Cl- and Na+ they increase K+, magnesium (Mg2+), and Ca2+ excretion.

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19 Loop Diuretics

20 Prototype drugs include: Furosemide Furosemide derivatives:
piretanide bumetanide Ethacrynic acid Torsemide

21 Loop diuretics are used in the treatment of CHF by reducing acute pulmonary edema and edema refractory to other agents. These agents are used to treat hypertension, especially in individuals with diminished renal function. They are also used to treat acute hypercalcemia and halide poisoning.

22 Loop diuretics produce hypotension and volume depletion, as well as hypokalemia, because of enhanced secretion of K+. They may also produce alkalosis due to enhanced H+ secretion. Mg2+ wasting can also occur Therapy is often instituted gradually to minimize electrolyte imbalances and volume depletion.

23 Loop diuretics can cause dose-related ototoxicity, more often in individuals with renal impairment.
These effects are more pronounced with ethacrynic acid than with furosemide. These agents should be administered cautiously in the presence of renal disease or with use of other ototoxic agents such as aminoglycosides. These agents can cause hypersensitivity reactions. Ethacrynic acid produces GI disturbances.

24 Potassium-sparing diuretics
reduce Na+ reabsorption reduce K+ secretion in the distal part of the nephron (collecting tubule). These are not potent diuretics when used alone They are primarily used in combination with other diuretics.

25 Antagonists of the mineralocorticoid (aldosterone) receptor include:
Eplerenone, which is highly selective Spironolactone, which binds to other nuclear receptors such as the androgen receptor

26 Mechanism. These agents inhibit the action of aldosterone by competitively binding to the mineralocorticoid receptor and preventing subsequent cellular events that regulate K+ and H+ secretion and Na+ reabsorption. An important action is a reduction in the biosynthesis of ENaC, the Na+ channel in principal cells of the collecting duct.

27 These agents are active only when endogenous mineralocorticoid is present
effects are enhanced when hormone levels are elevated. These agents are absorbed from the gastrointestinal tract and are metabolized in the liver therapeutic effects are achieved only after several days.

28 Therapeutic uses. These drugs are generally used in combination with a thiazide or loop diuretic to treat hypertension CHF refractory edema They are also used to induce diuresis in clinical situations associated with hyperaldosteronism: adrenal hyperplasia in the presence of aldosterone-producing adenomas when surgery is not feasible.

29 Adverse effects and contraindications
These agents can cause hyperkalemia, hyperchloremic metabolic acidosis, and arrhythmias. Spironolactone is associated with gynecomastia and can also cause menstrual abnormalities in women.

30 These drugs are contraindicated in renal insufficiency, especially in diabetic patients.
They are contraindicated in the presence of other potassium-sparing diuretics and should be used with extreme caution in individuals taking an angiotensin-converting enzyme (ACE) inhibitor.

31 Amiloride and triamterene
Mechanism They bind to ENaC and thereby: decrease absorption of Na+ and decrease excretion of K+ in the cortical collecting tubule, independent of the presence of mineralocorticoids.

32 These drugs produce diuretic effects 2—4 hours after oral administration.
Triamterene increases urinary excretion of Mg2+; amiloride does not triamterene and amiloride are metabolized in the liver. Both drugs are secreted in the proximal tubule.

33 Therapeutic uses. These agents are used to manage CHF, cirrhosis, and edema caused by secondary hyperaldosteronism. They are available in combination products containing thiazide or loop diuretics (e.g., triamterene/hydrochlorothiazide). Amiloride in combination with thiazide diuretics (e.g., amiloride/hydrochlorothiazide) is used to treat hypertension

34 Adverse effects and contraindications.
Amiloride and triamterene produce hyperkalemia, the most common adverse effect, and ventricular arrhythmias. Dietary potassium intake should be reduced. Minor adverse effects include nausea and vomiting. Use of these drugs is contraindicated in the presence of diminished renal function.

35 Carbonic anhydrase inhibitors
Carbonic anhydrase inhibitors inhibit carbonic anhydrase in all parts of the body. In the kidney, the effects are predominantly in the proximal tubule. These drugs reduce: HCO3- reabsorption Na+ uptake. They also inhibit excretion of hydrogen (H+)

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37 Carbonic anhydrase inhibitors are absorbed from the gastrointestinal tract and are secreted by the proximal tubule. Urine pH changes are observed within 30 minutes. Carbonic anhydrase inhibitors include: Sulfonamide derivatives: acetazolamide dichlorphenamide methazolamide.

38 Carbonic anhydrase inhibitors are rarely used as diuretics.
Useful in the treatment of: Glaucoma: decrease the rate of HCO3- formation in the aqueous humor and consequently reduce ocular pressure. Enhance renal secretion of uric acid and cysteine: produce alkalinization of urine Epilepsy: Raise levels of CO2 in brain and lowering of pH – raising seizure threshold and sedation Prophylaxis and treatment of acute mountain sickness

39 Adverse reactions include:
metabolic acidosis due to reduction in bicarbonate stores. Urine alkalinity decreases the solubility of calcium salts and increases the propensity for renal calculi formation. Potassium wasting may be severe. Following large doses, carbonic anhydrase inhibitors commonly produce drowsiness and paresthesias. Use of these drugs is contraindicated in the presence of hepatic cirrhosis.

40 Agents influencing water excretion
Mannitol Glycerin Urea These agents are: easily filtered poorly reabsorbed alter the diffusion of water relative to sodium by “binding” water. As a result, net reabsorption of Na+ is reduced. Mannitol and urea are administered intravenously.

41 Therapeutic uses Mannitol is used in prophylaxis of acute renal failure resulting from physical trauma or surgery. Even when filtration is reduced, sufficient mannitol usually enters the tubule to promote urine output. Mannitol may also be useful for reducing cerebral edema and intraocular pressure. Parenteral urea is approved for the reduction of intracranial and intraocular pressure.

42 Adverse effects and contraindications
Because the osmotic forces that reduce intracellular volume ultimately expand extracellular volume, serious adverse effects may occur in patients with CHF. Minor adverse effects include headache and nausea.

43 Glycerin is administered orally.
This drug is used primarily for ophthalmic procedures. Topical anhydrous glycerin is useful for corneal edema.

44 Agents that influence the action of ADH
They influence the permeability of the luminal surface of the medullary collecting duct to water by causing water-specific water channels called aquaporin II to be inserted into the plasma membrane. Under conditions of dehydration, ADH levels increase to conserve body water. Agents that elevate or mimic ADH are antidiuretic Agents that lower or antagonize ADH action are diuretic.

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46 Vasopressin or analogues
Therapeutic uses. These agents are useful in the management of ADH-sensitive diabetes insipidus. Desmopressin [DDAVP], one of the most useful analogues, is also used to treat nocturnal enuresis. Studies have suggested that vasopressin and its analogues are useful to maintain blood pressure in patients with septic shock.

47 Adverse effects and contraindications.
These drugs produce serious cardiac-related adverse effects, and they should be used with caution in individuals with coronary artery disease. Hyponatremia occurs in ~5% of patients.

48 Chlorpropamide, acetaminophen, indomethacin, and clofibrate
Mechanisms Chlorpropamide, acetaminophen, and indomethacin enhance the action of ADH, at least partially by reducing production of prostaglandins in the kidney. Clofibrate increases the release of ADH centrally. Therapeutic uses. These agents are useful as antidiuretics in diabetic patients.

49 ADH antagonists Demeclocycline Lithium carbonate
They may be useful in the treatment of syndrome of inappropriate ADH (SIADH) secretion as seen in some lung cancers.

50 Other diuretics Xanthine diuretics
act by increasing cardiac output and promoting a higher glomerular filtration rate. They are seldom used as diuretics, but diuresis occurs under other clinical applications (e.g., for bronchodilatation). Acidifying salts: (e.g., ammonium chloride) lower pH and increase lumen concentrations of Cl- and Na+. They are sometimes used in combination with high-ceiling diuretics to counteract alkalosis.

51 II. Nondiuretic Inhibitors of Tubular Transport
Nondiuretic inhibitors influence transport of organic anions, including the endogenous anion uric acid, and cations. Transport takes place in the proximal tubule; organic compounds enter a cell by Na+-facilitated diffusion and are excreted from the cell into the lumen by a specific organic ion transporter. Para-aminohippurate, not used clinically, is a classic compound used to study these phenomena.

52 Uricosuric agents Mechanism. increase excretion of uric acid.
Therapeutic uses: These drugs are often used in the treatment of gout.

53 Selected drugs: Probenecid Mechanism.
Probenecid is absorbed from the GI tract and is secreted by the proximal tubule. Probenecid inhibits secretion of organic acids (e.g., from the plasma to the tubular lumen). Probenecid was developed to decrease secretion of penicillin ( an organic acid) and thus prolong elimination of this antibiotic. Other drugs whose secretion is inhibited by probenecid include indomethacin and methotrexate.

54 At higher doses, probenecid also decreases reabsorption of uric acid by inhibiting URAT1, a urate transport protein. This results in a net increase in urate excretion and accounts for the drug's usefulness in treating gout.

55 Therapeutic uses. Probenecid is used to prevent gout in individuals with normal renal function. It is also used as an adjuvant to penicillin therapy when prolonged serum levels following a single dose are required or to enhance antibiotic concentrations in the CNS.

56 Adverse effects and contraindications.
The most common adverse effects of probenecid are hypersensitivity reactions and gastric irritation.

57 Sulfinpyrazone Mechanism.
Sulfinpyrazone is a strong organic acid that inhibits reabsorption of uric acid similarly to probenecid. It may also inhibit secretion of drugs transported by an organic acid carrier. Sulfinpyrazone is absorbed from the gastrointestinal tract and is secreted by the proximal tubule.

58 Adverse effects and contraindications.
Therapeutic uses. Sulfinpyrazone is used in the treatment of gout, often in combination with colchicine or a nonsteroidal antiinflammatory drug. Adverse effects and contraindications. Use of sulfinpyrazone is contraindicated in the presence of peptic ulcer disease.

59 Allopurinol Mechanism. Allopurinol is not a uricosuric agent.
It inhibits xanthine oxidase, which is involved in the synthesis of uric acid. Allopurinol is metabolized by xanthine oxidase to produce alloxanthine, which has long-lasting inhibitory effects on the enzyme; the net result is decreased production of uric acid. Therapeutic uses. Allopurinol is used in the treatment of gout.

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