Tocopherols chemistry

Basically, three reactions were evoked to support the occurrence of 5a-C-centered radicals 10 in tocopherol chemistry. The first one is the formation of 5a-substituted derivatives (8) in the reaction of a-tocopherol (1) with radicals and radical initiators. The most prominent example here is the reaction of 1 with dibenzoyl peroxide leading to 5a-a-tocopheryl benzoate (11) in fair yields,12 so that a typical radical recombination mechanism was postulated (Fig. 6.6). Similarly, low yields of 5a-alkoxy-a-tocopherols were obtained by oxidation of a-tocopherol with tert-butyl hydroperoxide or other peroxides in inert solvents containing various alcohols,23 24 although the involvement of 5 a-C-centered radicals in the formation mechanism was not evoked for explanation in these cases. 

The formation of 5a-a-tocopheryl benzoate (11) upon reaction of a-tocopherol (1) with dibenzoyl peroxide, which has usually been taken as solid proof of the involvement of 5a-C-centered radicals in tocopherol chemistry (see Fig. 6.6), was shown to proceed according to a nonradical, heterolytic mechanism involving o-QM 3 (Fig. 6.9). 

The last reaction commonly evoked to support the involvement of radical species 10 in tocopherol chemistry is the disproportionation of two molecules into the phenol a-tocopherol and the ort/zo-quinone methide 3 (Fig. 6.8), the latter immediately dimerizing into spiro dimer 9. This dimerization is actually a hetero-Diels-Alder process with inverse electron demand. It is largely favored, which is also reflected by the fact that spiro dimer 9 is an almost ubiquitous product and byproduct in vitamin E chemistry.28,29 The disproportionation mechanism was proposed to account for the fact that in reactions of tocopheroxyl radical 2 generated without chemical coreactants, that is, by irradiation, the spiro dimer 9 was the only major product found. 

The oxidation of a-tocopherol (1) to dimers29,50 and trimers15,51 has been reported already in the early days of vitamin E chemistry, including standard procedures for near-quantitative preparation of these compounds. The formation generally proceeds via orf/zo-quinone methide 3 as the key intermediate. The dimerization of 3 into spiro dimer 9 is one of the most frequently occurring reactions in tocopherol chemistry, being almost ubiquitous as side reaction as soon as the o-QM 3 occurs as reaction intermediate. Early accounts proposed numerous incorrect structures,52 which found entry into review articles and thus survived in the literature until today.22 Also several different proposals as to the formation mechanisms of these compounds existed. Only recently, a consistent model of their formation pathways and interconversions as well as a complete NMR assignment of the different diastereomers was achieved.28... 

Riboflavin, physiology and biochemistry of formation 84PHA805. Tocopherol, chemistry and natural occurrence of 81KPS263. Tocopherol, structure and functions of 86ACR194. 

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