Amiloride is a potassium-sparing diuretic that does not have much of a diuretic effect when compared to its potassium-sparing activity. It is a pyrazinoylguanidine derivative.

It is FDA indicated to be used adjunctively with thiazides (or other kaliuretic agents) for the treatment of chronic heart failure or uncomplicated essential hypertension to:

1. Help restore normal serum potassium concentrations in those who develop hypokalemia on kaliuretic therapy
2. Prevent hypokalemia in patients who would develop significant complications in the incident of hypokalemia 

Amiloride might also be useful as an off-label indication in Liddle syndrome[1] thiazolidinediones-induced edema, lithium-induced polyuria, cystic fibrosis, insulin-induced edema, and multiple myeloma.[1][2][3][4][5]

Amiloride works by inhibiting the epithelial sodium channels (ENaC) in the distal nephron (distal convoluted tubule and cortical collecting duct), lung, and colon. These ENaCs are composed of two domains that span the apical membrane. Those domains are M1 and M2. Intracellularly there C and N termini, while extracellularly, there is a large loop that contains 2 or 3 cysteine-rich domains. ENaCs consist of three subunits; alpha, beta, and gamma [6]. Mutation in beta or gamma subunits occurs in Liddle syndrome in which basal ENaCs activity increases. Amiloride is beneficial in Liddle syndrome.[7]

Usually, sodium moves down its electrochemical gradient to enter the tubular cells through the ENaCs. This gradient results from the basolateral membrane Na/K ATPase. Reabsorption of Na is associated with depolarization of the apical membrane, which creates a lumen-negative transepithelial potential difference. This potential difference enhances potassium secretion through the apical potassium channels and, subsequently, potassium excretion. Amiloride selectively inhibits ENaCs resulting in a decrease in hyperpolarization of the apical membrane and consequently decreases potassium, hydrogen, calcium, and magnesium secretion. Because amiloride inhibits ENaCs, it can also lead to mild natriuresis.[8][9] Amiloride also has the potential to cause vasodilation.[10] Decreased renal uric acid excretion might present when using amiloride for an extended period, and this is secondary to volume contraction and increased uric acid reabsorption in the proximal convoluted tubule.

Both the loop diuretics and thiazides will lead to increased Na concentration in the distal convoluted tubule and cortical collecting duct. This increase in Na concentration couples with increased Na reabsorption as well as increased potassium secretion and excretion. Therefore, co-administration of amiloride with thiazide or loop diuretics decreases their kaliuretic effect and augments their antihypertensive and diuretic effect. 

Amiloride might be useful in treating insulin-induced edema. In this condition, there is upregulation of ENaCs, which results in increased Na reabsorption and subsequently increased potassium secretion and excretion. Amiloride is not that effective in cases of hyperaldosteronism when compared to spironolactone and eplerenone.

Amiloride has the potential to induce apoptosis in multiple myeloma cell lines in mice, and therefore it might be used in the future for the treatment of relapsed multiple myeloma. Also, amiloride had a synergistic effect when combined with melphalan, lenalidomide, and dexamethasone.[5]

Dosing in adults for amiloride's FDA indications:

• Congestive heart failure: 5 to 10 mg by mouth once daily or in 2 divided doses
• Hypertension: 5 to 10 mg once orally each day or in 2 divided doses
• Thiazide-induced hypokalemia: 5 to 10 mg by mouth once daily or in 2 divided doses

Amiloride gets excreted unchanged while triamterene undergoes extensive metabolism in the liver. Oral amiloride dosing should optimally be with food to avoid gastrointestinal upset.

Amiloride has a FDA boxed warning for hyperkalemia, either alone or even when combined with hydrochlorothiazide.[11] Hyperkalemia might be fatal, especially in people with diabetes mellitus, elderly patients, and patients with renal impairment. Hyperkalemia tends to occur in patients not receiving a concomitant kaliuretic diuretic. When amiloride is used concomitantly with thiazides, the risk of hyperkalemia drops to 1 to 2%. 

Other adverse effects include[12]:

• Central nervous system: headache, fatigue, and dizziness
• Musculoskeletal system: muscle cramps and weakness
• Gastrointestinal system: nausea, vomiting, diarrhea/constipation, abdominal pain, and anorexia
• Endocrine and metabolic: glucose intolerance, hyperuricemia as a side effect of all potassium-sparing diuretics including amiloride, and hyperchloremic metabolic acidosis, hyponatremia, and gynecomastia. 
• Respiratory: dyspnea and cough
• Genitourinary: impotence 

Amiloride can cause fatal hyperkalemia in susceptible patients. It is contraindicated to use amiloride in the following conditions: Chronic renal insufficiency, concomitant use of drugs that blunt the renin-angiotensin-aldosterone system (angiotensin-converting enzyme inhibitors, beta-blockers, NSAIDs, and aliskiren), concomitant use of other potassium-sparing diuretics, anuria, diabetic nephropathy, and hypersensitivity to amiloride. The clinician should discontinue oral vitamin K administration in patients receiving potassium-sparing diuretics. Amiloride is acceptable during pregnancy since it is FDA pregnancy category B.