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Biguanide: Difference between revisions

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{{short description|Chemical compound}}
{{short description|Chemical compound}}
{{Pathnav|medication|diabetes medication|frame=1}}
{| class="wikitable sortable" style="width:100%"
|-
!一般名
!先発名
!class="unsortable"| 日本
!創薬/開発
!備考
|-
|[[Metformin/ja]]
|[https://sumitomo-pharma.jp/product/metgluco/ メトグルコ](Metgulco) ([https://pins.japic.or.jp/pdf/newPINS/00061908.pdf PI]) ([https://sumitomo-pharma.jp/product/metgluco/attachment/interv.html IF])
|販売
|[[住友ファーマ]]
|
|-
|}
{{chembox
{{chembox
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'''Biguanide''' ({{IPAc-en|b|aɪ|ˈ|g|w|ɒ|n|aɪ|d}}) is the organic compound with the formula HN(C(NH)NH<sub>2</sub>)<sub>2</sub>.  It is a colorless solid that dissolves in water to give highly basic solution.  These solutions slowly hydrolyse to [[ammonia]] and [[urea]].
'''Biguanide''' ({{IPAc-en|b|aɪ|ˈ|g|w|ɒ|n|aɪ|d}}) is the organic compound with the formula HN(C(NH)NH<sub>2</sub>)<sub>2</sub>.  It is a colorless solid that dissolves in water to give highly basic solution.  These solutions slowly hydrolyse to [[ammonia]] and [[urea]].


==Synthesis== <!--T:3-->
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==Synthesis==
Biguanide can be obtained from the reaction of [[dicyandiamide]] with [[ammonia]], via a [[pinner reaction|Pinner]]-type process.
Biguanide can be obtained from the reaction of [[dicyandiamide]] with [[ammonia]], via a [[pinner reaction|Pinner]]-type process.


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


==Biguanidine drugs== <!--T:6-->
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==Biguanidine drugs==
A variety of [[derivative (chemistry)|derivatives]] of biguanide are used as pharmaceutical drugs.
A variety of [[derivative (chemistry)|derivatives]] of biguanide are used as pharmaceutical drugs.


===Antihyperglycemic agents=== <!--T:7-->
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===Antihyperglycemic agents===
The term "biguanidine" often refers specifically to a class of drugs that function as oral antihyperglycemic [[drug]]s used for [[diabetes mellitus]] or [[prediabetes]] treatment.
The term "biguanidine" often refers specifically to a class of drugs that function as oral antihyperglycemic [[drug]]s used for [[diabetes mellitus]] or [[prediabetes]] treatment.


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====History==== <!--T:10-->
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====History====
{{details|metformin#History}}
{{details|metformin#History}}
''[[Galega officinalis]]'' (French lilac) was used in diabetes treatment for centuries. 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). Metformin has a much better safety profile, and it is the principal biguanide drug used in pharmacotherapy worldwide.
''[[Galega officinalis]]'' (French lilac) was used in diabetes treatment for centuries. 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). Metformin has a much better safety profile, and it is the principal biguanide drug used in pharmacotherapy worldwide.


====Mechanism of action==== <!--T:11-->
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====Mechanism of action====
The [[mechanism of action]] of biguanides is not fully understood, and many mechanisms have been proposed for metformin.
The [[mechanism of action]] of biguanides is not fully understood, and many mechanisms have been proposed for metformin.


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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)).
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)).


====Side effects and toxicity==== <!--T:16-->
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====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.
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=== <!--T:17-->
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===Antimalarial===
During WWII a British team led by [[Frank Rose (chemist)|Frank Rose]] discovered (see details there) that some biguanides are useful as [[antimalarial drug]]s. Much later it was demonstrated that they are prodrugs metabolised into active [[dihydrotriazine]] derivatives which, until recently, were believed to work by [[Dihydrofolate reductase inhibitor|inhibiting]] [[dihydrofolate reductase]]. Examples include:
During WWII a British team led by [[Frank Rose (chemist)|Frank Rose]] discovered (see details there) that some biguanides are useful as [[antimalarial drug]]s. Much later it was demonstrated that they are prodrugs metabolised into active [[dihydrotriazine]] derivatives which, until recently, were believed to work by [[Dihydrofolate reductase inhibitor|inhibiting]] [[dihydrofolate reductase]]. Examples include:
* [[Proguanil]] (>[[cycloguanil]])
* [[Proguanil]] (>[[cycloguanil]])
* [[Chlorproguanil]]
* [[Chlorproguanil]]


===Disinfectants=== <!--T:18-->
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===Disinfectants===
{{see also|Bisbiguanide}}
{{see also|Bisbiguanide}}
The disinfectants [[chlorhexidine]], [[polyaminopropyl biguanide]] (PAPB), [[polihexanide]], and [[alexidine]] feature biguanide [[functional group]]s.
The disinfectants [[chlorhexidine]], [[polyaminopropyl biguanide]] (PAPB), [[polihexanide]], and [[alexidine]] feature biguanide [[functional group]]s.
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