5-hydroxy-2-alkenal epoxide

The expected enone is obtained in 40% yield. A 15% yield of the product, resulting from hydroxy-directed epoxidation followed by oxidation to ketone, is obtained. A third product, obtained in 30% yield, can be explained by the equilibration of the initially formed allylic chromate ester with an isomeric chromate ester that directs the epoxidation of an alkene, giving an epoxy alcohol that is further oxidized to an... 

In analogy to the Peterson alkenation, the intermediate hydroxyphosphine oxidn (269) cm be prepared by addition to epoxide derivatives (268 Scheme 36). Overall yields are high for this process, and this sequence can be applied to the synthesis of phosphonate intermediates as well. Warren has studied hydroxy-directed epoxidation. Provided the allylic phosphine oxide is trisubstituted, as is (270) in equation (6S), these oxidations proceed with good selectivity. Ring opening can then be undertaken to generate the hyth-oxyphosphine oxide. 

For cyclizations via epoxide opening leading to C-glycosides and related compounds, see [2,204-206]. For the synthesis of C-glycosides and related compounds by episelenonium-mediated cyclizations, see [2, 207]. For episulfonium ion promoted cyclizations of hydroxy alkenes, see [2]. For the preparation of C-glycosides... 

Hydroxyl groups also participate as nucleophiles in a variety of other acid-catalyzed cyclizations of synthetic utility. One example is the Ritter reaction, which normally produces amides upon reaction of olefins or alcohols with nitriles. Cyclization occurs with 1,3-diols, hydroxy alkenes, or epoxides. Examples of each are given in Eqs. (74)-(76). 

As a further application of the reaction, the conversion of an endocyclic double bond to an c.xo-methylene is possible[382]. The epoxidation of an cWo-alkene followed by diethylaluminum amide-mediated isomerization affords the allylic alcohol 583 with an exo double bond[383]. The hydroxy group is eliminated selectively by Pd-catalyzed hydrogenolysis after converting it into allylic formate, yielding the c.ro-methylene compound 584. The conversion of carvone (585) into l,3-disiloxy-4-methylenecyclohexane (586) is an example[382]. 

The Pd-catalyzed hydrogenolysis of vinyloxiranes with formate affords homoallyl alcohols, rather than allylic alcohols regioselectively. The reaction is stereospecific and proceeds by inversion of the stereochemistry of the C—O bond[394,395]. The stereochemistry of the products is controlled by the geometry of the alkene group in vinyloxiranes. The stereoselective formation of stereoisomers of the syn hydroxy group in 630 and the ami in 632 from the ( )-epoxide 629 and the (Z)-epoxide 631 respectively is an example. 

The hydroxy oxygen of a peracid has a higher electrophilicity as compared to a carboxylic acid. A peracid 2 can react with an alkene 1 by transfer of that particular oxygen atom to yield an oxirane (an epoxide) 3 and a carboxylic acid 4. The reaction is likely to proceed via a transition state as shown in 5 (butterfly mechanism), where the electrophilic oxygen adds to the carbon-carbon n-hond and the proton simultaneously migrates to the carbonyl oxygen of the acid ... 

Epoxidation of conjugated dienes can be regioselective when one double bond is more electron-rich than the other otherwise mixtures of mono- and diepoxides will be obtained. When the alkene contains an adjacent stereocenter, the epoxidation can be diastereoselective [2]. Hydroxy groups can function as directing groups, causing the epoxidation to take place syn to the alcohol [2, 3]. 

A suspension of thallium (III) nitrate in hexane reacts with epoxides to give the corresponding -hydroxy nitrate esters in good yield. The same reagent in acetonitrile has been used to synthesize a-nitratoketones from substituted acetophenones, 1,2-dinitrate esters from alkenes, and 1,3-dinitrates from ring-opening nitration of cyclopropanes. ... 

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