Biguanide Explained

Biguanide is the organic compound with the formula HN(C(NH)NH2)2. It is a colorless solid that dissolves in water to give a highly basic solution. These solutions slowly hydrolyse to ammonia and urea.[1]

Synthesis

Biguanide can be obtained from the reaction of dicyandiamide with ammonia, via a Pinner-type process.

C2H4N4+NH3\longrightarrowC2H7N5

Biguanide was first synthesized by Bernhard Rathke in 1879.[2]

Biguanidine drugs

A variety of derivatives of biguanide are used as pharmaceutical drugs.

Antihyperglycemic agents

The term "biguanidine" often refers specifically to a class of drugs that function as oral antihyperglycemic drugs used for diabetes mellitus or prediabetes treatment.[3]

Examples include:

History

Galega officinalis (French lilac) was used in diabetes treatment for centuries.[4] In the 1920s, guanidine compounds were discovered in Galega extracts. Animal studies showed that these compounds lowered blood glucose levels. Some less toxic derivatives, synthalin A and synthalin B, were used for diabetes treatment, but after the discovery of insulin, their use declined. Biguanides were reintroduced into Type 2 diabetes treatment in the late 1950s. Initially phenformin was widely used, but its potential for sometimes fatal lactic acidosis resulted in its withdrawal from most pharmacopeias (in the U.S. in 1978).[5] Metformin has a much better safety profile, and it is the principal biguanide drug used in pharmacotherapy worldwide.

Mechanism of action

The mechanism of action of biguanides is not fully understood, and many mechanisms have been proposed for metformin.

Biguanides do not affect the output of insulin, unlike other hypoglycemic agents such as sulfonylureas and meglitinides. Therefore, they are effective in Type 2 diabetics; and in Type 1 diabetes when used in conjunction with insulin therapy.

Mainly used in Type II diabetes, metformin is considered to increase insulin sensitivity in vivo, resulting in reduced plasma glucose concentrations, increased glucose uptake, and decreased gluconeogenesis.

However, in hyperinsulinemia, biguanides can lower fasting levels of insulin in plasma. Their therapeutic uses derive from their tendency to reduce gluconeogenesis in the liver, and, as a result, reduce the level of glucose in the blood. Biguanides also tend to make the cells of the body more willing to absorb glucose already present in the bloodstream, and there again reducing the level of glucose in the plasma.

Biguanides have been shown to interact with copper, specifically in mitochondria, where they interfere with cell metabolism by chelating Copper in its 2+ oxidation state (Cu(II)).[6]

Side effects and toxicity

The most common side effect is diarrhea and dyspepsia, occurring in up to 30% of patients. The most important and serious side effect is lactic acidosis, therefore metformin is contraindicated in advanced chronic kidney disease. Kidney function should be assessed before starting metformin. Phenformin and buformin are more prone to cause acidosis than metformin; therefore they have been practically replaced by it. However, when metformin is combined with other drugs (combination therapy), hypoglycemia and other side effects are possible.

Antimalarial

During WWII a British team led by Frank Rose discovered (see details there) that some biguanides are useful as antimalarial drugs. Much later it was demonstrated that they are prodrugs metabolised into active dihydrotriazine derivatives which, until recently, were believed to work by inhibiting dihydrofolate reductase. Examples include:

Disinfectants

See also: Bisbiguanide. The disinfectants chlorhexidine, polyaminopropyl biguanide (PAPB), polihexanide, and alexidine feature biguanide functional groups.[7]

Notes and References

  1. Book: Güthner T, Mertschenk B, Schulz B . Guanidine and Derivatives . Ullmann's Encyclopedia of Industrial Chemistry . 2006 . Wiley-VCH . Weinheim . 10.1002/14356007.a12_545.pub2 . 3527306730 .
  2. Rathke . B. . Ueber Biguanid . Berichte der Deutschen Chemischen Gesellschaft . January 1879 . 12 . 1 . 776–784 . 10.1002/cber.187901201219.
  3. Book: Rang HP, Dale MM, Ritter KM, Moore PK . Pharmacology . 2003 . Churchill Livingstone . Edinburgh . 0-443-07145-4 . 5th . 388.
  4. Witters L . The blooming of the French lilac . J Clin Invest . 108 . 8 . 1105–7 . 2001 . 11602616 . 10.1172/JCI14178 . 209536 .
  5. Book: Tonascia S, Meinert CL . Clinical trials: design, conduct, and analysis . Oxford University Press . Oxford [Oxfordshire] . 1986 . 53–54, 59 . 0-19-503568-2.
  6. Solier . Stéphanie . Müller . Sebastian . Tatiana . Cañeque . Antoine . Versini . Arnaud . Mansart . Fabien . Sindikubwabo . Leeroy . Baron . Laila . Emam . Pierre . Gestraud . G. Dan . Pantoș . Vincent . Gandon . Christine . Gaillet . Ting-Di . Wu . Florent . Dingli . Damarys . Loew . Sylvain . Baulande . Sylvère . Durand . Valentin . Sencio . Cyril . Robil . François . Trottein . David . Péricat . Emmanuelle . Näser . Céline . Cougoule . Etienne . Meunier . Anne-Laure . Bègue . Hélène . Salmon . Nicolas . Manel . Alain . Puisieux . Sarah . Watson . Mark A. . Dawson . Nicolas . Servant . Guido . Kroemer . Djillali . Annane . Raphaël . Rodriguez . A druggable copper-signalling pathway that drives inflammation . Nature . 2023 . 1-9 . 10.1038/s41586-023-06017-4 . 37100912 . 10131557 .
  7. Tanzer JM, Slee AM, Kamay BA . Structural requirements of guanide, biguanide, and bisbiguanide agents for antiplaque activity . Antimicrobial Agents and Chemotherapy . 12 . 6 . 721–9 . December 1977 . 931371 . 430011 . 10.1128/aac.12.6.721 .