Exocyclic methylene alcohols oxides

Cyclization, solvolytic, 54, 84 Cycloalkene oxides, 1-methyl, conversion to exocyclic methylene alcohols, 53, 20 Cyclobutadiene, generation in situ, 50, 23... 

Ethyl vinyl ether, 54, 71 Exocyclic methylene alcohols, from 1-methylcycloalkene oxides, 53, 20 Extractor, 54, 90... 

Pinocarveol has been prepared by the autoxidation of a-pinene,5 by the oxidation of /S-pinene with lead tetraacetate,6 and by isomerization of a-pinene oxide with diisobutylalumi-num,7 lithium aluminum hydride,8 activated alumina,9 potassium ferf-butoxide in dimethylsulfoxide,10 and lithium diethylamide.11 The present method is preferred for the preparation of pinocarveol, since the others give mixtures of products. It also illustrates a general method for converting 1-methylcy-cloalkene oxides into the corresponding exocyclic methylene alcohols.11 The reaction is easy to perform, and the yields are generally high. 

Cydoalkene oxides, 1-methyl, conversion to exocyclic methylene alcohols, 53, 20... 

Studies directed toward the synthesis of bicyclomycin have resulted in the discovery of efficient routes to the construction of the 2-oxa-8,10-diazabicyclo[4.2.2]decane system (160). Thus, the monolactim ether (155) with a hydroxypropyl side chain at position 3, on oxidation with 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (DDQ), gave the product (156) in good yield, presumably via an iminium species (Scheme 51). No trace of the spiro compound (157) could be detected in this reaction. The formation of (156) is probably kinetically controlled. Prior protection of the alcohol as a silyl ether, followed by DDQ oxidation, gave the pyrazinone (158) subsequent deprotection and acid treatment gave the thermodynamically preferred spiro compound (159). The method has been extended to the synthesis of (160), having an exocyclic methylene this compound is a key intermediate in the total synthesis of bicyclomycin [88JCS(P1)2585]. 

The presence of an exocyclic methylene group in ignavine is indicated by the IR spectrnm (1645 and 892 cm i) and by formation of formaldehyde on ozonization. That the exocyclic methylene is involved in a secondary allylic alcohol system as in atisine was demonstrated by catalytic isomerization to a methyl ketone (1692 cm i) and by oxidation to a conjugated enone (1615, 1687 cm i) (72). 

Where functional groups are present which are more readily oxidized than the ether group, multiple reactions can occur. For example, in their total synthesis of (-i-)-tutin and (-i-)-asteromurin A, Yamada et al. observed concomitant oxidation of a secondary alcohol function in the oxidation of the ether (30) with ruthenium tetroxide (equation 24). The same group successfully achieved the simultaneous oxidation of both ether functions of the intermediate (31) in their related stereocontrolled syntheses of (-)-picrotox-inin and (-i-)-coriomyrtin (equation 25). Treatment of karahana ether (32) with excess ruthenium tetroxide resulted in the formation of the ketonic lactone (33) via oxidation of both the methylene group adjacent to the ether function and the exocyclic alkenic group (equation 26). In contrast, ruthenium tetroxide oxidation of the steroidal tetral drofuran (34) gave as a major product the lactone (35) in which the alkenic bond had been epoxidized. A small amount of the 5,6-deoxylactone (17%) was also isolated (equation 27). This transformation formed the basis of a facile introduction of the ecdysone side chain into C-20 keto steroids. 

Oxidative cyclocarbonylation-alkoxycarbonylation is usually observed when the reaction of alkenols and alkynols is carried out in the presence of external nucleophiles such as alcohols. /3-Lactones and /3-lactams bearing an exocyclic (Z)-(alkoxycar-bonyl)methylene moiety can be prepared according to a very simple oxidative technique starting from propynyl alcohols or amines. Geminal groups have been found to exert a powerful effect on cyclization. 

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