|
| Primary information |
|---|
| ID | 11271 |
| Therapeutic ID | Th1244 |
| Protein Name | Insulin human |
| Sequence | >Th1244_Insulin_human
GIVEQCCTSICSLYQLENYCN
|
| Molecular Weight | 5808 |
| Chemical Formula | C257H383N65O77S6 |
| Isoelectric Point | NA |
| Hydrophobicity | NA |
| Melting point | 81 °C |
| Half-life | Systemic insulin disposition (apparent terminal half-life) following oral inhalation of 4 to 48 units of human insulin was 120-206 minutes. |
| Description | Human Insulin, also known as Regular Insulin, is a short-acting form of insulin used for the treatment of hyperglycemia caused by Type 1 and Type 2 Diabetes. Human insulin is produced by recombinant DNA technology and is identical to endogenously produced insulin. Typically prescribed for the management of diabetes mellitus, insulin is a peptide hormone produced by beta cells of the pancreas that promotes glucose metabolism. Insulin is released from the pancreas following a meal to promote the uptake of glucose from the blood into internal organs and tissues such as the liver, fat cells, and skeletal muscle. Absorption of glucose into cells allows for its transformation into glycogen or fat for storage. Insulin also inhibits hepatic glucose production, enhances protein synthesis, and inhibits lipolysis and proteolysis among many other functions. Insulin is an important treatment in the management of Type 1 Diabetes (T1D) which is caused by an autoimmune reaction that destroys the beta cells of the pancreas, resulting in the body not being able to produce or synthesize the insulin needed to manage circulating blood sugar levels. As a result, people with T1D rely primarily on exogenous forms of insulin to lower glucose levels in the blood. Insulin is also used in the treatment of Type 2 Diabetes (T2D), another form of diabetes mellitus that is a slowly progressing metabolic disorder caused by a combination of genetic and lifestyle factors that promote chronically elevated blood sugar levels. Without treatment or improvement in non-pharmacological measures such as diet and exercise to lower blood glucose, high blood sugar eventually causes cellular resistance to endogenous insulin, and in the long term, damage to pancreatic islet cells. Insulin is typically prescribed later in the course of T2D, after trying several oral medications such as [DB00331], [DB01120], or [DB01261] have been tried, when sufficient damage has been caused to pancreatic cells that the body is no longer able to produce insulin on its own. Marketed as the brand name product Humulin R or Novolin R, human insulin begins to exert its effects within 30 minutes of subcutaneous administration, while peak levels occur 3-4 hours after administration. Due to its quick onset of action, human insulin is considered "bolus insulin" as it provides high levels of insulin in a short period of time to mimic the release of endogenous insulin from the pancreas after meals. Bolus insulin is often combined with once daily, long-acting "basal insulin" such as [DB01307], [DB09564], and [DB00047] to provide low concentrations of background insulin that can keep blood sugar stable between meals or overnight. Use of basal and bolus insulin together is intended to mimic the pancreas' production of endogenous insulin, with a goal of avoiding any periods of hypoglycemia. Human insulin is also available in an inhalable form, intended to be used as a bolus meal-time insulin. Exubera was the first inhaled insulin available on the market and was developed by Inhale Therapeutics (later named Nektar Therapeutics). Unfortunately, limited uptake by physicians and patients, poor sales, bulky packaging, and concerns over the possible impact on lung cancer development resulted in Exubera products being withdrawn from the US markets [A176005]. Exubera was followed by Afrezza, a monomeric inhaled insulin developed by Mannkind Corporation, which received FDA approval in 2016. While still available in the US, Afrezza has had similar concerns associated with its use, and had an FDA "black box" warning added to it to warn about use in patients with chronic lung disease. Afrezza does not currently have Health Canada or European Medicines Agency approval for marketing in Canada or the EU. Human Insulin is a 51 residue peptide hormone produced by recombinant DNA technology by inserting the human insulin gene into Escherichia coli bacteria or Saccharomyces cerevisiae. The structure is identical to native human insulin, with two amino acid chains covalently linked by disulfide bonds. Human insulin is also available in an intermediate-acting form as NPH (Neutral Protamine Hagedorn) as the marketed products Novolin N and Humulin N. NPH insulin is provided as a crystalline suspension of insulin with protamine and zinc, resulting in an onset of action in 1 to 3 hours, duration of action up to 24 hours, and peak action from 6 to 8 hours. Due to the added crystals, NPH insulin is typically cloudy when compared to other forms of insulin and has a neutral pH. Without an adequate supply of insulin to promote absorption of glucose from the bloodstream, blood sugar levels can climb to dangerously high levels and can result in symptoms such as fatigue, headache, blurred vision, and increased thirst. If left untreated, the body starts to break down fat, instead of glucose, for energy which results in a build-up of ketone acids in the blood and a syndrome called ketoacidosis, which is a life-threatening medical emergency. In the long term, elevated blood sugar levels increase the risk of heart attack, stroke, and diabetic neuropathy. |
| Indication/Disease | Human insulin is indicated to improve glycemic control in adults and pediatric patients with diabetes mellitus. |
| Pharmacodynamics | Insulin is a natural hormone produced by beta cells of the pancreas. In non-diabetic individuals, a basal level of insulin is supplemented with insulin spikes following meals. Postprandial insulin spikes are responsible for the metabolic changes that occur as the body transitions from a postabsorptive to absorptive state. Insulin promotes cellular uptake of glucose, particularly in muscle and adipose tissues, promotes energy storage via glycogenesis, opposes catabolism of energy stores, increases DNA replication and protein synthesis by stimulating amino acid uptake by liver, muscle and adipose tissue, and modifies the activity of numerous enzymes involved in glycogen synthesis and glycolysis. Insulin also promotes growth and is required for the actions of growth hormone (e.g. protein synthesis, cell division, DNA synthesis). |
| Mechanism of Action | The primary activity of insulin is the regulation of glucose metabolism. Insulin promotes glucose and amino acid uptake into muscle and adipose tissues, and other tissues except brain and liver. It also has an anabolic role in stimulating glycogen, fatty acid, and protein synthesis. Insulin inhibits gluconeogenesis in the liver. Insulin binds to the insulin receptor (IR), a heterotetrameric protein consisting of two extracellular alpha units and two transmembrane beta units. The binding of insulin to the alpha subunit of IR stimulates the tyrosine kinase activity intrinsic to the beta subunit of the receptor. The bound receptor is able to autophosphorylate and phosphorylate numerous intracellular substrates such as insulin receptor substrates (IRS) proteins, Cbl, APS, Shc and Gab 1. These activated proteins, in turn, lead to the activation of downstream signaling molecules including PI3 kinase and Akt. Akt regulates the activity of glucose transporter 4 (GLUT4) and protein kinase C (PKC) which play a critical role in metabolism and catabolism. |
| Toxicity | NA |
| Metabolism | The metabolism and elimination of orally inhaled human insulin are comparable to regular human insulin. |
| Absorption | When injected subcutaneously, the glucose-lowering effect of human insulin begins approximately 30 minutes post-dose. After a single subcutaneous administration of 0.1 unit/kg of human insulin to healthy subjects, peak insulin concentrations occurred between 1.5 to 2.5 hours post-dose. When administered in an inhaled form (as the product Afrezza), the time to maximum serum insulin concentration ranges from 10-20 minutes after oral inhalation of 4 to 48 units of human insulin. Serum insulin concentrations declined to baseline by approximately 60-240 minutes for these dose levels. Intrapatient variability in insulin exposure measured by AUC and Cmax is approximately 16% (95% CI 12-23%) and 21% (95% CI 16-30%), respectively. |
| NA |
| Clearance | NA |
| Categories | NA |
| Patents Number | 9393372 |
| Date of Issue | 19-07-2016 |
| Date of Expiry | 04-07-2029 |
| Drug Interaction | NA |
| Target | Insulin receptor,Insulin-like growth factor 1 receptor,Carboxypeptidase E,Protein NOV homolog,Low-density lipoprotein receptor-related protein 2,Insulin-like growth factor-binding protein 7 |
| Brand Name | Humulin 70/30 |
| Company | Eli Lilly and Company |
| Brand Description | Eli Lilly and Company |
| Prescribed For | Subcutaneous |
| Chemical Name | 100 |
| Formulation | HUMULIN 70/30 is contraindicated: During episodes of hypoglycemia, and In patients who have had hypersensitivity reactions to HUMULIN 70/30 or any of its excipients. |
| Physical Appearance | rash and/or itching over the whole body shortness of breath wheezing dizziness blurred vision fast heartbeat sweating difficulty breathing or swallowing weakness muscle cramps abnormal heartbeat large weight gain in a short period of time swelling of the arms, hands, feet, ankles, or lower legs |
| Route of Administration | Human insulin comes as a solution (liquid) and a suspension (liquid with particles that will settle on standing). to be injected subcutaneously (under the skin). Human insulin is usually injected subcutaneously several times a day, and more than one type of insulin may be needed. Your doctor will tell you which type(s) of insulin to use, how much insulin to use, and how often to inject insulin. Follow these directions carefully. Do not use more or less insulin or use it more often than prescribed by your doctor. |
| Recommended Dosage | Human insulin is used to control blood sugar in people who have type 1 diabetes (condition in which the body does not make insulin and therefore cannot control the amount of sugar in the blood) or in people who have type 2 diabetes (condition in which the blood sugar is too high because the body does not produce or use insulin normally) that cannot be controlled with oral medications alone. Human insulin is in a class of medications called hormones. Human insulin is used to take the place of insulin that is normally produced by the body. It works by helping move sugar from the blood into other body tissues where it is used for energy. It also stops the liver from producing more sugar. All of the types of insulin that are available work in this way. |
| Contraindication | NA |
| Side Effects | NA |
| Useful Link 1 | Link |
| Useful Link 2 | Link |
| Remarks | NA |