Oxidation rearrangements

Oxidative rearrangement takes place in the oxidation of the 1-vinyl-l-cyclo-butanol 31, yielding the cyclopentenone derivative 32[84], Ring contraction to cyclopropyl methyl ketone (34) is observed by the oxidation of 1-methylcyclo-butene (33)[85], and ring expansion to cyclopentanone takes place by the reaction of the methylenecyclobutane 35. [86,87]... 

When alkoxypyridazine 1-oxides are heated alone or in the presence of p-toluenesulfonic acid the methyl group migrates from the methoxy group to the A-oxide group. In this manner, 4-methoxypyridazine 1-oxide rearranges to l-methoxypyridazin-4(l//)-one, 5-methoxypyridazine 1-oxide to 2-methylpyridazin-5(2//)-one 1-oxide and substituted 3,6-dimethoxypyridazine 1-oxides to l,3-dimethoxypyridazin-6(l//)-ones. 

Besides displacement reactions, oxidations, rearrangements and cleavage of the sulfide linkage, the most important reactions take place at the sulfur atom. 

MEISENHEIMER N-Oxide Rearrangement Chlormalion at pyridlnes via rearrangemeirt ol N-oxides. 

POLONOVSKY N-oxide Rearrangement Conversion of heterocyclic N-oxIdes to a-acetoxyheterocycles... 

Glycol and o -hydroxy acid cleavage Oxidative decarboxylation Oxidative rearrangement of olefins... 

Kubota and co-workers describe a novel oxidative rearrangement of the diosphenol (58) of 17iS-hydroxyandrost-4-ene-2,3-dione to the A-nor-A -1,2-diketone (59) in 33 % yield by the action of specially prep d manganese dioxide in boiling acetone. The rate of ring contraction is very sensitive to the source of the oxidant, and a trace of dilute sulfuric acid in the reaction mixture causes oxidative fission of ring A. 

Oxidative rearrangement of 5a-cholestan-3-one (62) with hydrogen peroxide and a catalytic amount of selenic acid affords 2a-carboxy-A-nor-5a-cholestane, isolated in about 35 % yield as the methyl ester (63)." However, the reaction gives a complex mixture of A-nor- and seco-acids, and under... 

Ring contraction by oxidative rearrangements of A-ring a-diketones by manganese dioxide... 

Building blocks, useful for supramolecular or material science, have also been prepared using the Boekelheide reaction. Thus bipyridyl derivative 23 was subjected to the standard sequence of reactions (oxidation, rearrangement, and hydrolysis) to afford the diol 24. 

A series of oxidative rearrangements of tetrahydro-j8-carbolines may be rationalized on the basis of a general reaction of 2,3-disub-stituted indoles which was recently recognized by Taylor. Attack at the 4a-position of the tetrahydrocarboline (341) by an electrophile yields the indolenine derivative 342, which is in equilibrium with the isomeric species 342a. Compounds of structure 342 and 342a can undergo a variety of reactions leading to different products. 

Scheme 2.36 Possible mechanism of the oxidative rearrangement of vinylaziridines.

Whereas exo-norbornene oxide rearranges to nortricyclanol on treatment with strong base through transannular C-H insertion (Scheme 5.11), endo-norbornene oxide 64 gives norcamphor 65 as the major product (Scheme 5.14) [15, 22]. This product arises from 1,2-hydrogen migration very little transannular rearrangement is observed. These two reaction pathways are often found to be in competition with one another, and subtle differences in substrate structure, and even in the base employed, can have a profound influence on product distribution. 

Formation of a 6-hydroxydihydropyran-3-one by the oxidative rearrangement of a furan followed by its conversion to a pyrylium ylide forms part of a synthesis of the taxane skeleton <96T14081>. 

The ylide 44, prepared from the corresponding diazine and tetracyanoethylene oxide, rearranges in methanol the give the 1,3-diazepine 45 <96TL1587>. The x-ray geometry for 45 is reported. 

Examination of the reactions of a wide variety of olefins with TTN in methanol (92) has revealed that in the majority of cases oxidative rearrangement is the predominant reaction course (cf. cyclohexene, Scheme 9). Further examples are shown in Scheme 18, and the scope and limitations of this procedure for the oxidative rearrangement of various classes of simple olefins to aldehydes and ketones have been defined. From the experimental point of view these reactions are extremely simple, and most of them are... 

FIGURE 6.39 Synthesis of 4-oxo-a-tocopherol (55) and its oxidative rearrangement into... 

Bentley and Murray (201) reported another method for synthesis of protopine alkaloids allocryptopine (392) and cryptopalmatine (395) from tetrahydroprotoberberine /V-oxides (35a and 400) through oxidative rearrangement with potassium chromate (Scheme 73). 

The pseudobenzylisoquinoline alkaloids are fairly widespread in nature, being found among members of Berberidaceae, Annonaceae, Fumariaceae, and Ranunculaceae. The biogenesis of the pseudobenzylisoquinoline alkaloids assumes their formation from protoberberinium salts by C-8—C-8a bond scission in a Baeyer-Villiger-type oxidative rearrangement to produce the enamides of type 73 and 74. These amides may be further biotransformed either to rugosinone (76) type alkaloids by hydrolytic N-deformylation followed by oxidation or to ledecorine (75) by enzymatic reduction. These transformations were corroborated by in vitro studies (80-82). It is suggested that enamide seco alkaloids may be precursors of aporphine alkaloids (80), on one hand, and of cularine alkaloids (77), on the other. 

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