Multicap
Multicap Uses, Dosage, Side Effects, Food Interaction and all others data.
A basic constituent of lecithin that is found in many plants and animal organs. It is important as a precursor of acetylcholine, as a methyl donor in various metabolic processes, and in lipid metabolism.
This compound is needed for good nerve conduction throughout the CNS (central nervous system) as it is a precursor to acetylcholine (ACh). Choline is also needed for gallbladder regulation, liver function and lecithin (a key lipid) formation. Choline also aids in fat and cholesterol metabolism and prevents excessive fat build up in the liver. Choline has been used to mitigate the effects of Parkinsonism and tardive dyskinesia. Choline deficiencies may result in excessive build-up of fat in the liver, high blood pressure, gastric ulcers, kidney and liver dysfunction and stunted growth.
A metallic element found in certain minerals, in nearly all soils, and in mineral waters. It is an essential constituent of hemoglobin, cytochrome, and other components of respiratory enzyme systems. Its chief functions are in the transport of oxygen to tissue (hemoglobin) and in cellular oxidation mechanisms. Depletion of iron stores may result in iron-deficiency anemia. Iron is used to build up the blood in anemia.
The major activity of supplemental iron is in the prevention and treatment of iron deficiency anemia. Iron has putative immune-enhancing, anticarcinogenic and cognition-enhancing activities.
Potassium is an essential nutrient, like Calcium and Magnesium. It was identified as a shortfall nutrient by the 2015-2020 Advisory Committee of Dietary Guidelines for Americans. Many conditions and diseases interfere with normal body potassium balance, and underconsumption of potassium is one example. Hypokalemia (low potassium) or hyperkalemia (high potassium) may result, manifesting as various signs and symptoms. Some examples of potassium-related complications include life-threatening arrhythmia, neuromuscular dysfunction, diarrhea, nausea, and vomiting.
Various pharmacological preparations have been formulated to replenish potassium. They are available in an assortment of tablet, injection, and other forms, depending on the setting and condition being treated. Potassium is often a key ingredient for intravenous fluids, given to patients in clinical settings for rehydration, nutrition, and replenishment of electrolytes. Examples of potassium formulations include potassium citrate, potassium chloride, and potassium with dextrose and sodium chloride.
Potassium maintains an electrolyte gradient on cell surfaces, keeping at specific concentrations inside and outside of the cell; this impacts fluid and electrolyte balance, nerve transmission, muscle contraction, as well as cardiac and kidney function. Clinical evidence has associated potassium intake with lower blood pressure in adults, reducing the risk stroke and heart disease. Dietary potassium may exert beneficial effects on bone loss in the elderly and kidney stones. Consumption of white vegetables, which are normally high in potassium, is associated with a lower risk of stroke.
Trade Name | Multicap |
Generic | Choline + Colecalciferol [vit D3] + Elemental Magnesium + Iron + Pantothenic Acid [vit B5] + Phosphorus + Potassium + Pyridoxine [vit B6] + Retinol [vit A] + Tocopherol [vit E] |
Type | Capsule |
Therapeutic Class | |
Manufacturer | Glenmark Pharmaceuticals |
Available Country | India |
Last Updated: | September 19, 2023 at 7:00 am |
Uses
Choline is a nutrient found in a wide variety of vitamins including pre-natal formulations.
For nutritional supplementation, also for treating dietary shortage or imbalance
Iron is an essential element commonly used for the treatment of patients with documented iron deficiency.
Used in preventing and treating iron-deficiency anemia.
Phosphorus is a medication indicated in the treatment of hypophosphatemia.
Potassium is a medication used to treat hypokalemic conditions and to clear the colon prior to colonoscopy.
General uses of potassium
Potassium is indicated to treat a variety of conditions. Firstly, it used to replenish potassium that has been depleted by conditions including but not limited to malabsorption, decreased intake, or excess sodium intake. The causes of potassium deficiency are numerous. The following indications for potassium are not comprehensive, but include the main indications for which this nutrient is used. Various products and preparations contain potassium.
Potassium chloride
Potassium chloride is one of the main preparations of potassium used in a clinical setting. The oral solution is indicated for the prevention and treatment of hypokalemia presenting with or without metabolic alkalosis, in patients who have failed conservative management with potassium-rich foods or diuretic dose titrations. The injection form of potassium chloride is indicated to replenish potassium in patients who are not feasible candidates for oral potassium. Highly concentrated potassium is intended for the treatment of potassium deficiency in fluid restricted individuals who cannot tolerate fluid volumes normally associated with injected potassium solutions that contain lower concentrations. Finally, the extended-release tablet preparation of potassium chloride is used to treat hypokalemia with or without metabolic alkalosis, to treat digitalis intoxication, and to manage patients with hypokalemic familial periodic paralysis. It is also used in the prevention of hypokalemia in those who are at a high risk of negative clinical outcomes if hypokalemia occurs; patients on digitalis or those with cardiac arrhythmias would be at particular risk of negative outcomes.
Potassium chloride with dextrose and sodium chloride
This liquid preparation is is indicated in a clinical setting as a source of water, calories and electrolytes. Potassium acetate solution is meant as an alternative to potassium chloride, replenishing potassium and added to large volume infusion fluids for intravenous injection.
Potassium citrate
The potassium citrate preparation is used for the management of renal tubular acidosis (RTA) with calcium stones (nephrolithiasis); calcium oxalate stones by any cause, and uric acid nephrolithiasis (with or without calcium stones). This regimen also includes adequate water intake (leading to a urine out put of 2 L/day or more) and sodium restriction.
Multicap is also used to associated treatment for these conditions: Nutritional supplementationAnemia, Iron Deficiency (ID), Iron Deficiency Anemia (IDA), Restless Legs Syndrome (RLS), Concomitant myelosuppressive chemotherapy, Nutritional supplementation, Dietary supplementationBone Loss, Nutritional supplementationCaloric Intake, Electrolyte and fluid balance conditions, Hydration, Hypokalemia, Potassium
How Multicap works
Choline is a major part of the polar head group of phosphatidylcholine. Phosphatidylcholine's role in the maintenance of cell membrane integrity is vital to all of the basic biological processes: information flow, intracellular communication and bioenergetics. Inadequate choline intake would negatively affect all these processes. Choline is also a major part of another membrane phospholipid, sphingomyelin, also important for the maintenance of cell structure and function. It is noteworthy and not surprising that choline deficiency in cell culture causes apoptosis or programmed cell death. This appears to be due to abnormalities in cell membrane phosphatidylcholine content and an increase in ceramide, a precursor, as well as a metabolite, of sphingomyelin. Ceramide accumulation, which is caused by choline deficiency, appears to activate Caspase, a type of enzyme that mediates apoptosis. Betaine or trimethylglycine is derived from choline via an oxidation reaction. Betaine is one of the factors that maintains low levels of homocysteine by resynthesizing L-methionine from homocysteine. Elevated homocysteine levels are a significant risk factor for atherosclerosis, as well as other cardiovascular and neurological disorders. Acetylcholine is one of the major neurotransmitters and requires choline for its synthesis. Adequate acetylcholine levels in the brain are believed to be protective against certain types of dementia, including Alzheimer's disease.
Iron is necessary for the production of hemoglobin. Iron-deficiency can lead to decreased production of hemoglobin and a microcytic, hypochromic anemia.
Potassium ion is the primary intracellular cation found in virtually all body tissues. The total amount of body potassium in adults is estimated at 45 millimole (mmol)/kg body weight (about 140 g for an adult weighing 175 pounds; 1 mmol = 1 milliequivalent or 39.1 mg of potassium). Potassium mainly stays in cells, and a small amount can be found in the extracellular fluid. The amount of potassium that stays in the cell (intracellular) is 30 times that of extracellular concentration, creating a transmembrane gradient, regulated by the sodium-potassium (Na+/K+) ATPase transporter. This is an important gradient for nerve conduction, muscle contractions, and renal function. Vomiting, diarrhea, renal disease, medications, and other conditions that alter potassium excretion or shift it inside or outside of cells. In healthy patients individuals with normal renal function, markedly high or low potassium levels are rare.
Effect on blood pressure
Potassium decreases reduces intravascular volume, by reducing sodium reabsorption through an increase in urinary sodium excretion. This short-term effect, however, does not explain the long-term effects of potassium on blood pressure. Increased plasma potassium levels that occur through intake are associated with vasodilation occurring via stimulation of the sodium-potassium adenosine triphosphatase pump (Na+/-K+ATPase) and opening of potassium channels of the sodium-potassium adenosine triphosphatase pump. Other possible mechanisms of action for potassium may include alterations in barroreflex sensitivity and hormone sensitivity in vascular smooth muscle and cells of the sympathetic nervous system.
Effect on electrolyte balance and body systems
The potassium gradient across the membrane of a cell regulates cell membrane potential, maintained predominantly by the sodium-potassium (Na+/-K+ ATPase pump). Transmembrane electro-chemical gradients encourage diffusion of Na+ extracellularly and K+ intracellularly. Potassium supplementation prevents hypokalemia to maintain this balance and is often used in an oral solution or injection form in the clinical setting, preventing harmful effects such as arrhythmias, abnormal muscle function, and neurological disturbances. When activated, the Na+/-K+ ATPase pump exchanges two extracellular K+ ions for three intracellular sodium (Na+) ions, impacting membrane potential via either excitation or inhibition. This is especially important in the homeostasis of the nervous system, kidney, and cardiac muscle tissue. The body and cell distributions of potassium in normal conditions are known as internal and external balance, respectively. Reduced serum potassium (or imbalance) increases the risk of ventricular arrhythmia, heart failure and left ventricular hypertrophy (LVH).
Toxicity
Oral rat LD50: 3400 mg/kg
Acute iron overdosage can be divided into four stages. In the first stage, which occurs up to six hours after ingestion, the principal symptoms are vomiting and diarrhea. Other symptoms include hypotension, tachycardia and CNS depression ranging from lethargy to coma. The second phase may occur at 6-24 hours after ingestion and is characterized by a temporary remission. In the third phase, gastrointestinal symptoms recur accompanied by shock, metabolic acidosis, coma, hepatic necrosis and jaundice, hypoglycemia, renal failure and pulmonary edema. The fourth phase may occur several weeks after ingestion and is characterized by gastrointestinal obstruction and liver damage. In a young child, 75 milligrams per kilogram is considered extremely dangerous. A dose of 30 milligrams per kilogram can lead to symptoms of toxicity. Estimates of a lethal dosage range from 180 milligrams per kilogram and upwards. A peak serum iron concentration of five micrograms or more per ml is associated with moderate to severe poisoning in many.
The oral LD50 of potassium chloride in rats is 2600 mg/kg.
Overdose information
An overdose of potassium may result in hyperkalemia, and in some cases, death due to various causes. Signs and symptoms of an overdose of potassium are mainly cardiovascular, neurological and musculoskeletal in nature. Arrhythmia, changes in cardiac conduction, including astystole, bradycardia, heart block, ventral fibrillation, and ventricular tachycardia may occur. In addition, hypotension may also occur along with cardiac ECG changes. Muscular weakness and respiratory muscle paralysis may occur, in addition to paresthesia. In case of an overdose, discontinue potassium administration, reduce the dose, and monitor fluid levels and electrolyte concentrations in addition to acid-base balance. Corrective therapy, such as insulin administration or potassium binding drugs, may be required. Offer supportive care and resuscitation as deemed necessary.
Important note regarding hyperkalemia
Normally, hyperkalemia is asymptomatic and only detected by laboratory testing (at values of 6.5-8.0 mEq/L) and ECG changes (peaked T- waves, lost P-waves, ST depression, and a prolonged QT interval). Muscle paralysis and cardiac arrest may occur in the advanced stages of hyperkalemia, at potassium concentrations of 9-12 mEq/L.
Volume of Distribution
Potassium is present in almost all body tissues. Approximately 98% of potassium is maintained intracellularly in muscular tissue, the liver, and red blood cells. The remainder is distributed extracellularly.
Elimination Route
The efficiency of absorption depends on the salt form, the amount administered, the dosing regimen and the size of iron stores. Subjects with normal iron stores absorb 10% to 35% of an iron dose. Those who are iron deficient may absorb up to 95% of an iron dose.
When taken orally from a dietary source, potassium is mainly absorbed via passive diffusion in the small intestine. Approximately 90% of potassium is absorbed, and maintains concentrations both inside and outside cells. The kidneys can adapt to variable potassium intake in healthy individuals, but a minimum of 5 mmol (about 195 mg) dietary potassium is measured to be excreted in the urine.
Some studies have measured the absorption various forms of potassium from dietary supplements. Results from a clinical trial in 2016 showed that potassium gluconate supplements are 94% absorbed, which is similar to the absorption rate from potatoes. An older study advised that liquid forms of potassium are absorbed a few hours post-administration. Enteric coated tablets of potassium chloride are not absorbed as rapidly as liquid forms, due to their delayed release design.
Half Life
In one clinical study, the apparent half-life of oral potassium was between 1.6 and 14 hours. A radio tracer study determined that the biological half-life of radiolabeled potassium ranges from 10 to 28 days.
Clearance
Potassium is freely filtered in the kidney with most of an ingested amount being reabsorbed into the circulation (70%–80%) by the proximal tubule and loop of Henle. Secretion of potassium by the distal nephron in the kidney varies and dependent on the intracellular potassium concentration, luminal potassium concentration concentration, in addition to cellular permeability.
Elimination Route
Potassium is excreted primarily in the urine, excreted in small amounts in the stool, and negligibly in perspiration (sweat). The renal system regulates potassium excretion according to dietary intake. Potassium excretion rises quickly in healthy patients after ingestion unless body stores have been depleted. Potassium undergoes glomerular filtration, tubular reabsorption, and distal tubular secretion. Renal clearance of potassium shifts between net tubular secretion and reabsorption, depending on the clinical circumstances.
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