Vitamin is the "generic descriptor" name for any
vitamers of vitamin . Animals, including humans, can convert cyanocobalamin to any one of the active vitamin compounds. Cyanocobalamin is one of the most widely manufactured vitamers in the vitamin family (the family of chemicals that function as when put into the body), because cyanocobalamin is the most air-stable of the forms, and is the easiest to purify after it is produced by
bacterial fermentation. It can be obtained as dark red crystals or as an amorphous red powder. Cyanocobalamin is
hygroscopic in the
anhydrous form, and sparingly soluble in water (1:80). It is stable to
autoclaving for short periods at . The vitamin
coenzymes are unstable in light. Vitamin additionally becomes inactive when exposed to intense heat or electromagnetic radiation.
Chemical reactions In the cobalamins,
cobalt normally exists in the trivalent state, Co(III). However, under reducing conditions, the cobalt center is reduced to Co(II) or even Co(I), which are usually denoted as and , for reduced and super reduced respectively. and can be prepared from cyanocobalamin by controlled potential reduction, or chemical reduction using
sodium borohydride in alkaline solution,
zinc in
acetic acid, or by the action of
thiols. Both and are stable indefinitely under oxygen-free conditions. appears orange-brown in solution, while appears bluish-green under natural daylight, and purple under artificial light. is one of the most nucleophilic species known in aqueous solution. This property allows the convenient preparation of cobalamin analogs with different
substituents, via
nucleophilic attack on
alkyl halides and vinyl halides. For example, cyanocobalamin can be converted to its analog cobalamins via reduction to , followed by the addition of the corresponding
alkyl halides,
acyl halides,
alkene or
alkyne.
Steric hindrance is the major limiting factor in the synthesis of the coenzyme analogs. For example, no reaction occurs between
neopentyl chloride and , whereas the secondary alkyl halide analogs are too unstable to be isolated. This effect may be due to the strong coordination between
benzimidazole and the central cobalt atom, pulling it down into the plane of the
corrin ring. The
trans effect determines the polarizability of the Co–C bond so formed. However, once the
benzimidazole is detached from cobalt by quaternization with
methyl iodide, it is replaced by or
hydroxyl ions. Various secondary alkyl halides are then readily attacked by the modified to give the corresponding stable cobalamin analogs. The products are usually extracted and purified by phenol-methylene chloride extraction or by column chromatography. Cobalamin analogs prepared by this method include the naturally occurring coenzymes
methylcobalamin and
cobamamide, and other cobalamins that do not occur naturally, such as vinylcobalamin, carboxymethylcobalamin and cyclohexylcobalamin. This reaction is under review for use as a catalyst for
chemical dehalogenation, organic reagent and photosensitized catalyst systems. ==Production==