Isolyte S In Dextrose
Isolyte S In Dextrose Uses, Dosage, Side Effects, Food Interaction and all others data.
Dextrose is a monosaccharide that is used as a source of calories and water for hydration. It helps to reduce loss of body protein and nitrogen. It also promotes glycogen deposition in the liver. When used with insulin, it stimulates the uptake of potassium by cells, especially in muscle tissue, thus lowering serum potassium levels.
Blood glucose is an obligatory energy source in humans involved in various cellular activities, and it also acts as a signalling molecule for diverse glucose-sensing molecules and proteins. Glucose undergoes oxidation into carbon dioxide, water and yields energy molecules in the process of glycolysis and subsequent citric cycle and oxidative phosphorylation. Glucose is readily converted into fat in the body which can be used as a source of energy as required. Under a similar conversion into storage of energy, glucose is stored in the liver and muscles as glycogen. Glucose stores are mobilized in a regulated manner, depending on the tissues' metabolic demands. Oral glucose tablets or injections serve to increase the supply of glucose and oral glucose administration is more effective in stimulating insulin secretion because it stimulates the incretin hormones from the gut, which promotes insulin secretion.
Magnesium chloride salts are highly soluble in water and the hydrated form of magnesium chloride can be extracted from brine or sea water.
Magnesium is important as a cofactor in many enzymatic reactions in the body involving protein synthesis and carbohydrate metabolism (at least 300 enzymatic reactions require magnesium). Actions on lipoprotein lipase have been found to be important in reducing serum cholesterol and on sodium/potassium ATPase in promoting polarization (eg, neuromuscular functioning).
Potassium chloride is a major cation of the intracellular fluid. It plays an active role in the conduction of nerve impulses in the heart, brain and skeletal muscle; contraction of cardiac skeletal and smooth muscles; maintenance of normal renal function, acid-base balance, carbohydrate metabolism and gastric secretion.
The potassium ion is in the principle intracellular cation of most body tissues. Potassium ions participate in a number of essential physiological processes including the maintenance of intracellular tonicity, the transmission of nerve impulses, the contraction of cardiac, skeletal and smooth muscle, and the maintenance of normal renal function. The intracellular concentration of potassium is approximately 150 to 160 mEq per liter. The normal adult plasma concentration is 3.5 to 5 mEq per liter. An active ion transport system maintains this gradient across the plasma membrane. Potassium is a normal dietary constituent and under steady-state conditions the amount of potassium absorbed from the gastrointestinal tract is equal to the amount excreted in the urine. The usual dietary intake of potassium is 50 to 100 mEq per day. Potassium depletion will occur whenever the rate of potassium loss through renal excretion and/or loss from the gastrointestinal tract exceeds the rate of potassium intake. Such depletion usually develops as a consequence of therapy with diuretics, primarily or secondary hyperaldosteronism, diabetic ketoacidosis, or inadequate replacement of potassium in patients on prolonged parenteral nutrition. Depletion can develop rapidly with severe diarrhea, especially if associated with vomiting. Potassium depletion due to these causes is usually accompanied by concomitant loss of chloride and is manifested by hypokalemia and metabolic alkalosis. Potassium depletion may produce weakness, fatigue, disturbances of cardiac rhythm (primarily ectopic beats), prominent U-waves in the electrocardiogram, and, in advanced cases, flaccid paralysis and/or impaired ability to concentrate urine. If potassium depletion associated with metabolic alkalosis cannot be managed by correcting the fundamental cause of the deficiency, e.g., where the patient requires long-term diuretic therapy, supplemental potassium in the form of high potassium food or potassium chloride may be able to restore normal potassium levels. In rare circumstances (e.g., patients with renal tubular acidosis) potassium depletion may be associated with metabolic acidosis and hyperchloremia. In such patients, potassium replacement should be accomplished with potassium salts other than the chloride, such as potassium bicarbonate, potassium citrate, potassium acetate, or potassium gluconate.
Sodium Acetate is chemically designated CH3COONa, a hygroscopic powder very soluble in water. Sodium acetate could be used as additives in food, industry, concrete manufacture, heating pads and in buffer solutions. Medically, sodium acetate is important component as an electrolyte replenisher when given intravenously. It is mainly indicated to correct sodium levels in hyponatremic patients. It can be used also in metabolic acidosis and for urine alkalinization.
Sodium is the principal cation of extracellular fluid. It comprises more than 90% of total cations at its normal plasma concentration of approximately 140 mEq/liter. The sodium ion exerts a primary role in controlling total body water and its distribution. Acetate ions acts as hydrogen ion acceptor which is alternative to bicarbonate.
Sodium chloride is the major extracellular cation. It is important in electrolyte and fluid balance, osmotic pressure control and water distribution as it restores sodium ions. It is used as a source of electrolytes and water for hydration, treatment of metabolic acidosis, priming solution in haemodialysis and treatment of hyperosmolar diabetes. It is also used as diluents for infusion of compatible drug additives.
Sodium, the major cation of the extracellular fluid, functions primarily in the control of water distribution, fluid balance, and osmotic pressure of body fluids. Sodium is also associated with chloride and bicarbonate in the regulation of the acid-base equilibrium of body fluid.Chloride, the major extracellular anion, closely follows the metabolism of sodium, and changes in the acid-base balance of the body are reflected by changes in the chloride concentration.
Trade Name | Isolyte S In Dextrose |
Generic | Dextrose + Magnesium Chloride + Potassium Chloride + Sodium Acetate + Sodium Chloride + Sodium Gluconate |
Type | |
Therapeutic Class | |
Manufacturer | |
Available Country | USA |
Last Updated: | September 19, 2023 at 7:00 am |
Uses
Dextrose is administered as a parenteral nutrition solution in the treatment of carbohydrate depletion and hypoglycaemic coma. Because of its high dextrose content it is used in the treatment of cerebral edema, shock, circulatory collapse, unconsciousness and to correct hyperkalaemia with or without insulin.
Magnesium chloride is an ionic compound and source of magnesium used for electrolyte replenishment and conditions associated with magnesium deficiencies.
Magnesium chloride is used in several medical and topical (skin related) applications. Magnesium chloride usp, anhydrous uses as electrolyte replenisher, pharmaceutic necessity for hemodialysis and peritoneal dialysis fluids.
Potassium chloride is used for drug induced hypokalemia, liver cirrhosis, nausea, vomiting, cholera, diarrhoea, muscular weakness, paralysis, cardiac and congestive heart failure, diabetic ketoacidosis, ulcerative colitis, weakness, anorexia, drowsiness, Cushing's syndrome, pyloric stenosis, low blood pressure etc.
Sodium acetate is a compound used for electrolyte replenishment and total parenteral nutrition (TPN) therapy.
Injection, USP 40 mEq is indicated as a source of sodium, for addition to large volume intravenous fluids to prevent or correct hyponatremia in patients with restricted or no oral intake. It is also useful as an additive for preparing specific intravenous fluid formulas when the needs of the patient cannot be met by standard electrolyte or nutrient solutions. Sodium acetate and other bicarbonate precursors are alkalinising agents, and can be used to correct metabolic acidosis, or for alkalinisation of the urine.
Sodium Chloride Nasal Drops is used for dry nasal membranes including dry nose resulting from cold and allergy medications. It moistens dry nasal passages from dry climates or from airplane travel, may help dissolve mucus from study noses and clears the nose after surgery. This sterile saline solution is also used to cleanse various parts of the body (wounds, body cavities) and medical equipment (e.g., bandages, catheters, drainage tubes). It is also used as a mixing solution (diluent) for other medications used to irrigate the body (e.g., bacitracin, polymyxin).
Isolyte S In Dextrose is also used to associated treatment for these conditions: Arrhythmia, Caloric Deficit, Edema of the cerebrum, Metabolic Alkalosis, Hypoglycemic reaction, Blood Specimen Collection, Electrolyte replacement, Nutritional supplementation, Parenteral Nutrition, Parenteral rehydration therapy, Plasmapheresis, Positive cardiac inotropic effect, Total parenteral nutrition therapy, Urine alkalinization therapy, Fluid and electrolyte maintenance therapyElectrolyte imbalance, Magnesium Deficiency, Mild Metabolic acidosis, Automated peritoneal dialysis, Continuous Renal Replacement Therapy, Continuous ambulatory peritoneal dialysis therapy, Fluid replacement therapy, Hemodialysis Treatment, Irrigation therapy, Organ Preservation, Parenteral rehydration therapy, Peritoneal dialysis therapy, Total parenteral nutrition therapy, Urine alkalinization therapy, Fluid and electrolyte maintenance therapyDehydration, Dry Mouth, Hypokalemia, Hypotonic Dehydration, Hypovolaemia, Isotonic Dehydration, Markedly Reduced Food Intake, Metabolic Acidosis, Hypodermoclysis, Mild Metabolic acidosis, Mild, moderate Metabolic Acidosis, Ocular edema, Acid-Base Balance, Bowel preparation therapy, Electrolyte replacement, Fluid replacement therapy, Hemodialysis Treatment, Hemofiltration, Parenteral Nutrition, Parenteral rehydration therapy, Plasma Volume Replacement, Urine alkalinization therapy, Fluid and electrolyte maintenance therapyHyponatremia, Hypovolaemia, Mild, moderate Metabolic Acidosis, Irrigation therapy, Nutritional supplementation, Oral rehydration therapy, Parenteral Nutrition, Parenteral rehydration therapy, Total parenteral nutrition therapy, Priming solution for infusionAllergic Rhinitis (AR), Corneal Edema, Dehydration, Dehydration Hypertonic, Fluid Loss, Hemodilution, Hypertension Intracranial, Hypokalemia, Hyponatremia, Hypotonic Dehydration, Hypovolaemia, Increased Intra Ocular Pressure (IOP), Inflammation of the Nasal Mucosa, Isotonic Dehydration, Metabolic Acidosis, Nasal Congestion, Nasal irritation, Oliguria caused by Acute Renal Failure (ARF), Potassium deficiency, Sinusitis, Skin Irritation, Sodium Depletion, Dryness of the nose, Hypochloremic state, Mild Metabolic acidosis, Mild, moderate Metabolic Acidosis, Electrolyte replacement, Fluid replacement therapy, Heart-Lung-Machine, Oral rehydration therapy, Parenteral Nutrition, Parenteral rehydration therapy, Peritoneal dialysis therapy, Plasma Volume Replacement, Regional Citrate Anticoagulation (RCA), Renal Replacement Therapies, Urine alkalinization therapy, Wound irrigation therapy, Ear wax removal, Fluid and electrolyte maintenance therapy, Increased renal excretion of toxic substances, Maintenance source of fluid and electrolytes, Parenteral drug administration, Reducing brain mass
How Isolyte S In Dextrose works
Glucose supplies most of the energy to all tissues by generating energy molecules ATP and NADH during a series of metabolism reactions called glycolysis. Glycolysis can be divided into 2 main phases where the preparatory phase is initiated by the phosphorylation of glucose by a hexokinase to form glucose 6-phosphate. The addition of the high-energy phosphate group activates glucose for subsequent breakdown in later steps of glycolysis and is the rate-limiting step. Products end up as substrates for following reactions, to ultimately convert C6 glucose molecule into two C3 sugar molecules. These products enter the energy-releasing phase where total of 4ATP and 2NADH molecules are generated per one glucose molecule. The total aerobic metabolism of glucose can produce up to 36 ATP molecules. This energy-producing reactions of glucose is limited to D-glucose as L-glucose cannot be phosphorlyated by hexokinase. Glucose can act as precursors to generate other biomolecules such as vitamin C. It plays a role as a signaling molecule to control glucose and energy homeostasis. Glucose can regulate gene transcription, enzyme activity, hormone secretion, and the activity of glucoregulatory neurons. The types, number and kinetics of glucose transporters expressed depends on the tissues and fine-tunes glucose uptake, metabolism, and signal generation in order to preserve cellular and whole body metabolic integrity .
Mechanism of action of magnesium chloride studied in 10 adult volunteers. Results suggested magnesium ion in duodenum is relatively weak stimulus to pancreas and gall bladder. It is weak stimulant to cholecystokinin release and inhibits net jejunal water absorption. The oral administration of a single 800 mg dose of magnesium chloride in healthy volunteers resulted in a diminished rate of intraluminal lipid and protein digestion. The most pronounced effect of magnesium chloride, however, was a decreased gastric emptying rate of both test meals. After correction for gastric emptying, no differences were noted in intraluminal lipid or protein digestion. Therefore, the lower lipid levels noted after magnesium supplementation are unlikely to be the result of altered lipid assimilation. Magnesium chloride slows gastric emptying but does not influence lipid digestion.
Supplemental potassium in the form of high potassium food or potassium chloride may be able to restore normal potassium levels.
It works as a source of sodium ions especially in cases of hyponatremic patients. Sodium has a primary role in regulating extracellular fluid volume. It controls water distribution, fluid and electrolyte balance and the osmotic pressure of body fluids. Sodium is also involved in nerve conduction, muscle contraction, acid-base balance and cell nutrient uptake.
Sodium and chloride — major electrolytes of the fluid compartment outside of cells (i.e., extracellular) — work together to control extracellular volume and blood pressure. Disturbances in sodium concentrations in the extracellular fluid are associated with disorders of water balance.
Dosage
Isolyte S In Dextrose dosage
The volume and rate of infusion of dextrose solution will depend upon the requirements of the individual patient and the judgement of the physician.
The maximum rate at which dextrose can be infused without producing glycosuria is 0.5 gm/kg/hr.
The usual recommended flow rate for adult is 10-35 drops per minute infused intravenously.
Intravenous-
Hyperkalaemia:
- Adult: 25-50 g combined with 10 units of regular insulin, administered over 30-60 minutes; may repeat if necessary. Alternatively, 25 g combined with 5-10 units of regular insulin infused over 5 minutes; may repeat if necessary.
- Child and infants: 0.5-1 g/kg (using 25% or 50% solution) combined with regular insulin (1 unit for every 4-5 g dextrose given); infuse over 2 hr, may repeat if necessary.
Intravenous-
Hypoglycaemia:
- Adult: 10-25 g (40-100 ml of 25% solution or 20-50 ml of 50% solution). Doses may be repeated in severe cases.
- Child: ≤6 mth: 0.25-0.5 g/kg/dose; >6 mth: 0.5-1 g/kg/dose. Doses may be repeated in severe cases. Max: 25 g/dose.
Oral-
Hypoglycaemia:
- Adult: 10-20 g as single dose; may repeat in 10 min if needed.
- Child: >2 yr: 10-20 g as single dose; may repeat in 10 min if needed.
Oral:Dosage must be adjusted to the individual needs of each patient.
- Adults: In severe deficiencies 3-6 tablets or 4-8 teaspoonful or 25-50 mmol per day orally in divided doses for some days with fruit juice, sweet or plain water.
- Children: ½-1 teaspoonful twice daily or 1-3 mmol/kg body weight a day in several divided doses.
Patient should take Potassium chloride with meals.
Intravenous:
Severe acute hypokalaemia:
- Adult: If serum potassium level >2.5 mEq/L, give at a rate not exceeding 10 mEq/hr in a concentration of up to 40 mEq/L. Max dose: 200 mEq/24 hr. If serum potassium level <2 mEq/L, may infuse at a rate of up to 40 mEq/hr. Continuous cardiac monitoring is essential. Max dose: 400 mEq/24 hr.
75 mg KCl equivalent to 1 mmol K+
Infants, children & adults: 2-6 drops into each nostril as needed daily
Use in Children: Safe for pediatrics
It should not be administered by SC or IM route. Dextrose should be infused through the largest available peripheral vein.
Side Effects
Venous thrombosis, phlebitis, hypovolemia, hypervolemia, dehydration, oedema, fever, mental confusion, unconsciousness, hyperosmolar syndrome, hyperglycaemia, hypokalaemia, acidosis, hypophosphataemia, hypomagnesemia, polyuria, glycosuria, ketonuria, nausea, diarrhoea, polydipsia, vein irritation, tissue necrosis, pulmonary oedema, tachypnoea.
GI ulceration (sometimes with haemorrhage and perforation or with late formation of strictures) following the use of enteric-coated K chloride preparation; hyperkalaemia. Oral: Nausea, vomiting, diarrhoea and abdominal cramps. IV: Pain or phloebitis; cardiac toxicity.
No side Effects are expected to occur. However stinging, sneezing, increased nasal discharge, or salty taste may occur in some cases.
Toxicity
Oral LD50 value in rats is 25800mg/kg. The administration of glucose infusions can cause fluid and/or solute overloading resulting in dilution of the serum electrolyte concentrations, over-hydration, congested states, or pulmonary oedema. Hypersensitivity reactions may also occur including anaphylactic/anaphylactoid reactions from oral tablets and intravenous infusions.
Mouse LD50 775mg/kg (intraperitoneal) Mouse LD50 : 7600mg/kg (oral) Rat LD 50 : 8100mg/kg (oral) Rat LD50 176mg/kg (intravenous) Severe toxicity occurs most often after intravenous infusions. It can also occur after chronic excessive oral doses, often in patients with renal insufficiency. Early manifestations are lethargy, hyporeflexia, followed by weakness, paralysis, hypotension, ECG changes (prolonged PR and QRS intervals), CNS depression, seizures, and respiratory depression. In overdose, magnesium impairs neuromuscular transmission, manifested as weakness and hyporeflexia.
The administration of oral potassium salts to persons with normal excretory mechanisms for potassium rarely causes serious hyperkalemia. However, if excretory mechanisms are impaired, of if potassium is administered too rapidly intravenously, potentially fatal hyperkalemia can result. It is important to recognize that hyperkalemia is usually asymptomatic and may be manifested only by an increased serum potassium concentration (6.5-8.0 mEq/L) and characteristic electrocardiographic changes (peaking of T-waves, loss of P-wave, depression of S-T segment, and prolongation of the QT interval). Late manifestations include muscle paralysis and cardiovascular collapse from cardiac arrest (9-12 mEq/L).
LD50: 25956 mg/kg (Rat.)
The rare inadvertent intravascular administration or rapid intravascular absorption of hypertonic sodium chloride can cause a shift of tissue fluids into the vascular bed, resulting in hypervolemia, electrolyte disturbances, circulatory failure, pulmonary embolism, or augmented hypertension.
Precaution
Concentrated dextrose solution should not be infused rapidly or for a long period. It may be hazardous in patients with impaired hepatic or renal function and severe sepsis.
Care should be taken to avoid circulatory overload, particularly in patients with cardiac insufficiency. Caution must be exercised in the administration of these injections to patients receiving corticosteroids or corticotropin. These injections should be used with caution in patients with overt or subclinical diabetes mellitus.
Parenteral drug products should be inspected visually for particulate matter and discoloration prior to administration whenever solution and container permit. Do not administer unless solution is clear and seal is intact.
Renal or adrenocortical insufficiency; cardiac disease; acute dehydration; extensive tissue destruction. Pregnancy. Ensure adequate urine output; monitor plasma-potassium and other electrolyte concentrations. Discontinue treatment if severe nausea, vomiting or abdominal distress develops. Accumulation of potassium may occur in renal impairment.
Interaction
There is no drug drug interaction and none well documented.
Potassium-sparing diuretics, ACE inhibitors, ciclosporin and potassium-containing drugs. Antimuscarinics delay gastric emptying time consequently increasing risk of GI adverse effects esp of solid oral dosage forms.
Volume of Distribution
The mean volume of distribution after intravenous infusion is 10.6L.
Bone (50% to 60%); extracellular fluid (1% to 2%)
The volume of distribution is 0.64 L/kg.
Elimination Route
Polysaccharides can be broken down into smaller units by pancreatic and intestinal glycosidases or intestinal flora. Sodium-dependent glucose transporter SGLT1 and GLUT2 (SLC2A2) play predominant roles in intestinal transport of glucose into the circulation. SGLT1 is located in the apical membrane of the intestinal wall while GLUT2 is located in the basolateral membrane, but it was proposed that GLUT2 can be recruited into the apical membrane after a high luminal glucose bolus allowing bulk absorption of glucose by facilitated diffusion . Oral preparation of glucose reaches the peak concentration within 40 minutes and the intravenous infusions display 100% bioavailability.
Oral: Inversely proportional to amount ingested; 40% to 60% under controlled dietary conditions; 15% to 36% at higher doses
Potassium is a normal dietary constituent and under steady-state conditions the amount of potassium absorbed from the gastrointestinal tract is equal to the amount excreted in the urine.
It is readily available in the circulation after IV administration.
Absorption of sodium in the small intestine plays an important role in the absorption of chloride, amino acids, glucose, and water. Chloride, in the form of hydrochloric acid (HCl), is also an important component of gastric juice, which aids the digestion and absorption of many nutrients.
Half Life
The approximate half-life is 14.3 minutes following intravenous infusion. Gut glucose half-life was markedly higher in females (79 ± 2 min) than in males (65 ± 3 min, P < 0.0001) and negatively related to body height (r = -0.481; P < 0.0001).
Elimination half-life has been reported to be 27.7 hours following an overdose of 400 mEq magnesium in an adult.
17 minutes
Clearance
The mean metabolic clearance rate of glucose (MCR) for the 10 subjects studied at the higher insulin level was 2.27 ± 0.37 ml/kg/min at euglycemia and fell to 1.51±0.21 ml/kg/ at hyperglycemia. The mean MCR for the six subjects studied at the lower insulin level was 1.91 ± 0.31 ml/kg/min at euglyglycemia.
Maximum magnesium clearance is directly proportional to creatinine clearance.
Elimination Route
Glucose can be renally excreted.
Magnesium is excreted in urine. Unabsorbed magnesium is excreted in feces
Potassium is a normal dietary constituent and, under steady-state conditions, the amount of potassium absorbed from the gastrointestinal tract is equal to the amount excreted in the urine. Potassium depletion will occur whenever the rate of potassium loss through renal excretion and/or loss from the gastrointestinal tract exceeds the rate of potassium intake.
Both the sodium and bicarbonate ions are excreted mainly in the urine. Some sodium is excreted in the feces, and small amounts may also be excreted in saliva, sweat, bile and pancreatic secretions.
Substantially excreted by the kidneys.
Pregnancy & Breastfeeding use
Pregnancy Category C. Animal reproduction studies have shown an adverse effect on the fetus and there are no adequate and well-controlled studies in humans, but potential benefits may warrant use of the drug in pregnant women despite potential risks.
Category C: Either studies in animals have revealed adverse effects on the foetus (teratogenic or embryocidal or other) and there are no controlled studies in women or studies in women and animals are not available. Drugs should be given only if the potential benefit justifies the potential risk to the foetus.
It is unknown if this medication passes into breast milk. Consult with your doctor before breast-feeding.
Contraindication
Concentrated dextrose solution is contraindicated in patients with Glucose-Galactose Malabsorption Syndrome and severe hydration. The infusion of hypertonic dextrose injections is contraindicated in patients having intracranial or intraspinal hemorrhage, in patients who are severely dehydrated, in patients who are anuric, and in patients in hepatic coma. Solutions containing dextrose may be contraindicated in patients with known allergy to corn or corn products.
Hyperchloraemia, severe renal or adrenal insufficiency.
Tell your doctor about your medical history, especially of heart problems (e.g., congestive heart failure), lung problems (pulmonary edema), kidney problems, low levels of potassium (hypokalemia), high levels of sodium (hypernatremia), and any allergies.
Acute Overdose
Reevaluate patient's condition and institute appropriate symptomatic treatment.
Storage Condition
Store at 25°C.
Intravenous: Store at 15-30° C.
Oral: Store below 30° C.
Innovators Monograph
You find simplified version here Isolyte S In Dextrose