Drugs used in diabetes treat diabetes mellitus by lowering the glucose level in the blood. With the exceptions of insulin, exenatide, liraglutide and pramlintide, all are administered orally and are thus also called oral hypoglycemic agents or oral antihyperglycemic agents. There are different classes of anti-diabetic drugs, and their selection depends on the nature of the diabetes, age and situation of the person, as well as other factors.
Diabetes mellitus type 1 is a disease caused by the lack of insulin. Insulin must be used in type 1, which must be injected.
Diabetes mellitus type 2 is a disease of insulin resistance by cells. Type 2 diabetes mellitus is the most common type of diabetes. Treatments include (1) agents that increase the amount of insulin secreted by the pancreas, (2) agents that increase the sensitivity of target organs to insulin, and (3) agents that decrease the rate at which glucose is absorbed from the gastrointestinal tract.
Several groups of drugs, mostly given by mouth, are effective in type 2, often in combination. The therapeutic combination in type 2 may include insulin, not necessarily because oral agents have failed completely, but in search of a desired combination of effects. The great advantage of injected insulin in type 2 is that a well-educated patient can adjust the dose, or even take additional doses, when blood glucose levels measured by the patient, usually with a simple meter, as needed by the measured amount of sugar in the blood.
Insulin is usually given subcutaneously, either by injections or by an insulin pump. Research of other routes of administration is underway. In acute-care settings, insulin may also be given intravenously. Insulins are typically characterized by the rate at which they are metabolized by the body, yielding different peak times and durations of action. Faster-acting insulins peak quickly and are subsequently metabolized, while longer-acting insulins tend to have extended peak times and remain active in the body for more significant periods.
Examples of rapid acting insulins (peak time at ~1 hour) include:
Examples of short acting insulins (peak time between 2-4 hours) include:
Examples of intermediate acting insulins (peak time between 4-10 hours) include:
Examples of long acting insulins (duration ~24 hours, often with no peak) include:
Insulin degludec is sometimes classed separately as an "ultra-long" acting insulin due to its duration of action of approximately 42 hours, compared with 24 hours for most other long acting insulin preparations.
Most anti-diabetic agents are contraindicated in pregnancy, in which insulin is preferred.
Most studies involving vanadium compounds have employed vanadium salts, mainly vanadyl sulfate, and dose-limiting side effects were reported at therapeutic doses. One organic vanadium compound, bis(ethylmaltolato)oxovanadium(IV), had improved efficacy compared to the vanadyl sulfate and was selected for Phase 1 and 2 clinical trials.
Insulin sensitizers address the core problem in type 2 diabetes – insulin resistance.
Biguanides reduce hepatic glucose output and increase uptake of glucose by the periphery, including skeletal muscle. Although it must be used with caution in patients with impaired liver or kidney function, metformin, a biguanide, has become the most commonly used agent for type 2 diabetes in children and teenagers. Among common diabetic drugs, metformin is the only widely used oral drug that does not cause weight gain.
Typical reduction in glycated hemoglobin (A1C) values for metformin is 1.5–2.0%
Metformin is usually the first-line medication used for treatment of type 2 diabetes. In general, it is prescribed at initial diagnosis in conjunction with exercise and weight loss, as opposed to in the past, where it was prescribed after diet and exercise had failed. There is an immediate release as well as an extended-release formulation, typically reserved for patients experiencing gastrointestinal side-effects. It is also available in combination with other oral diabetic medications.
Thiazolidinediones (TZDs), also known as "glitazones," bind to PPARγ, a type of nuclear regulatory protein involved in transcription of genes regulating glucose and fat metabolism. These PPARs act on peroxysome proliferator responsive elements (PPRE). The PPREs influence insulin-sensitive genes, which enhance production of mRNAs of insulin-dependent enzymes. The final result is better use of glucose by the cells.
Typical reductions in glycated hemoglobin (A1C) values are 1.5–2.0%. Some examples are:
Multiple retrospective studies have resulted in a concern about rosiglitazone's safety, although it is established that the group, as a whole, has beneficial effects on diabetes. The greatest concern is an increase in the number of severe cardiac events in patients taking it. The ADOPT study showed that initial therapy with drugs of this type may prevent the progression of disease, as did the DREAM trial. The American Association of Clinical Endocrinologists (AACE), which provides clinical practice guidelines for management of diabetes, retains thiazolidinediones as recommended first, second, or third line agents for type 2 diabetes mellitus, as of their 2019 executive summary, over sulfonylureas and α-glucosidase inhibitors. However, they are less preferred than GLP-1 agonists or SGLT2 inhibitors, especially in patients with cardiovascular disease (which liraglutide, empagliflozin, and canagliflozin are all FDA approved to treat).
Concerns about the safety of rosiglitazone arose when a retrospective meta-analysis was published in the New England Journal of Medicine. There have been a significant number of publications since then, and a Food and Drug Administration panel voted, with some controversy, 20:3 that available studies "supported a signal of harm", but voted 22:1 to keep the drug on the market. The meta-analysis was not supported by an interim analysis of the trial designed to evaluate the issue, and several other reports have failed to conclude the controversy. This weak evidence for adverse effects has reduced the use of rosiglitazone, despite its important and sustained effects on glycemic control. Safety studies are continuing.
In contrast, at least one large prospective study, PROactive 05, has shown that pioglitazone may decrease the overall incidence of cardiac events in people with type 2 diabetes who have already had a heart attack.
The LYN kinase activator tolimidone has been reported to potentiate insulin signaling in a manner that is distinct from the glitazones. The compound has demonstrated positive results in a Phase 2a clinical study involving 130 diabetic subjects.
Sulfonylureas were the first widely used oral anti-hyperglycemic medications. They are insulin secretagogues, triggering insulin release by inhibiting the KATP channel of the pancreatic beta cells. Eight types of these pills have been marketed in North America, but not all remain available. The "second-generation" drugs are now more commonly used. They are more effective than first-generation drugs and have fewer side-effects. All may cause weight gain.
Current clinical practice guidelines from the AACE rate sulfonylureas (as well as glinides) below all other classes of antidiabetic drugs in terms of suggested use as first, second, or third line agents - this includes bromocriptine, the bile acid sequestrant colesevelam, α-glucosidase inhibitors, TZDs (glitazones), and DPP-4 inhibitors (gliptins). The low cost of most sulfonylureas, however, especially when considering their significant efficacy in blood glucose reduction, tends to keep them as a more feasible option in many patients - neither SGLT2 inhibitors nor GLP-1 agonists, the classes most favored by the AACE guidelines after metformin, are currently available as generics.
Sulfonylureas bind strongly to plasma proteins. Sulfonylureas are useful only in type 2 diabetes, as they work by stimulating endogenous release of insulin. They work best with patients over 40 years old who have had diabetes mellitus for under ten years. They cannot be used with type 1 diabetes, or diabetes of pregnancy. They can be safely used with metformin or glitazones. The primary side-effect is hypoglycemia.
Typical reductions in glycated hemoglobin (A1C) values for second-generation sulfonylureas are 1.0–2.0%.
Meglitinides help the pancreas produce insulin and are often called "short-acting secretagogues." They act on the same potassium channels as sulfonylureas, but at a different binding site. By closing the potassium channels of the pancreatic beta cells, they open the calcium channels, thereby enhancing insulin secretion.
They are taken with or shortly before meals to boost the insulin response to each meal. If a meal is skipped, the medication is also skipped.
Typical reductions in glycated hemoglobin (A1C) values are 0.5–1.0%.
Adverse reactions include weight gain and hypoglycemia.
Alpha-glucosidase inhibitors are "diabetes pills" but not technically hypoglycemic agents because they do not have a direct effect on insulin secretion or sensitivity. These agents slow the digestion of starch in the small intestine, so that glucose from the starch of a meal enters the bloodstream more slowly, and can be matched more effectively by an impaired insulin response or sensitivity. These agents are effective by themselves only in the earliest stages of impaired glucose tolerance, but can be helpful in combination with other agents in type 2 diabetes.
Typical reductions in glycated hemoglobin (A1C) values are 0.5–1.0%.
These medications are rarely used in the United States because of the severity of their side-effects (flatulence and bloating). They are more commonly prescribed in Europe. They do have the potential to cause weight loss by lowering the amount of sugar metabolized.
Incretins are insulin secretagogues. The two main candidate molecules that fulfill criteria for being an incretin are glucagon-like peptide-1 (GLP-1) and gastric inhibitory peptide (glucose-dependent insulinotropic peptide, GIP). Both GLP-1 and GIP are rapidly inactivated by the enzyme dipeptidyl peptidase-4 (DPP-4).
Glucagon-like peptide (GLP) agonists bind to a membrane GLP receptor. As a consequence, insulin release from the pancreatic beta cells is increased. Endogenous GLP has a half-life of only a few minutes, thus an analogue of GLP would not be practical. As of 2019, the AACE lists GLP-1 agonists, along with SGLT2 inhibitors, as the most preferred anti-diabetic agents after metformin. Liraglutide in particular may be considered first-line in diabetic patients with cardiovascular disease, as it has received FDA approval for reduction of risk of major adverse cardiovascular events in patients with type 2 diabetes.
These agents may also cause a decrease in gastric motility, responsible for the common side-effect of nausea, and is probably the mechanism by which weight loss occurs.
GLP-1 analogs resulted in weight loss and had more gastrointestinal side-effects, while in general DPP-4 inhibitors were weight-neutral and increased risk for infection and headache, but both classes appear to present an alternative to other antidiabetic drugs. However, weight gain and/or hypoglycemia have been observed when DPP-4 inhibitors were used with sulfonylureas; effect on long-term health and morbidity rates are still unknown.
A result in one RCT comprising 206 patients aged 65 or older (mean baseline HgbA1c of 7.8%) receiving either 50 or 100 mg/d of Sitagliptin was shown to reduce HbA1c by 0.7% (combined result of both doses). A combined result of 5 RCTs enlisting a total of 279 patients aged 65 or older (mean baseline HbA1c of 8%) receiving 5 mg/d of Saxagliptin was shown to reduce HbA1c by 0.73%. A combined result of 5 RCTs enlisting a total of 238 patients aged 65 or older (mean baseline HbA1c of 8.6%) receiving 100 mg/d of Vildagliptin was shown to reduce HbA1c by 1.2%. Another set of 6 combined RCTs involving Alogliptin (approved by FDA in 2013) was shown to reduce HbA1c by 0.73% in 455 patients aged 65 or older who received 12.5 or 25 mg/d of the medication.
Amylin agonist analogues slow gastric emptying and suppress glucagon. They have all the incretins actions except stimulation of insulin secretion. As of 2007[update], pramlintide is the only clinically available amylin analogue. Like insulin, it is administered by subcutaneous injection. The most frequent and severe adverse effect of pramlintide is nausea, which occurs mostly at the beginning of treatment and gradually reduces. Typical reductions in A1C values are 0.5–1.0%.
SGLT-2 inhibitors block the re-uptake of glucose in the renal tubules, promoting loss of glucose in the urine. This causes both mild weight loss, and a mild reduction in blood sugar levels with little risk of hypoglycemia. Oral preparations may be available alone or in combination with other agents. Along with GLP-1 agonists, they are considered preferred second or third agents for type 2 diabetics sub-optimally controlled with metformin alone, according to most recent clinical practice guidelines. Because they are taken by mouth, rather than injected (like GLP-1 agonists), patients who are injection-averse may prefer these agents over the former. They may be considered first line in diabetic patients with cardiovascular disease, especially heart failure, as these medications have been shown to reduce the risk of hospitalization in patients with such comorbidities. Because they are not available as generic medications, however, cost may limit their feasibility for many patients.
The side effects of SGLT-2 inhibitors are derived directly from their mechanism of action; these include an increased risk of: ketoacidosis, urinary tract infections, candidal vulvovaginitis, and hypoglycemia.
The following table compares some common anti-diabetic agents, generalizing classes, although there may be substantial variation in individual drugs of each class. When the table makes a comparison such as "lower risk" or "more convenient" the comparison is with the other drugs on the table.
|Comparison of anti-diabetic medication|
|Sulfonylurea (glyburide, glimepiride, glipizide)||Stimulating insulin release by pancreatic beta cells by inhibiting the KATP channel|
|Metformin||Acts on the liver to reduce gluconeogenesis and causes a decrease in insulin resistance via increasing AMPK signalling.||
|Alpha-glucosidase inhibitor (acarbose, miglitol, voglibose)||Reduces glucose absorbance by acting on small intestine to cause decrease in production of enzymes needed to digest carbohydrates||
|Thiazolidinediones (Pioglitazone, Rosiglitazone)||Reduce insulin resistance by activating PPAR-γ in fat and muscle||
Many anti-diabetes drugs are available as generics. These include:
No generics are available for dipeptidyl peptidase-4 inhibitors (Januvia, Onglyza) and other combinations.