Conjugated carbonyl compounds, epoxidations

Another important asymmetric epoxidation of a conjugated systems is the reaction of alkenes with polyleucine, DBU and urea H2O2, giving an epoxy-carbonyl compound with good enantioselectivity. The hydroperoxide anion epoxidation of conjugated carbonyl compounds with a polyamino acid, such as poly-L-alanine or poly-L-leucine is known as the Julia—Colonna epoxidation Epoxidation of conjugated ketones to give nonracemic epoxy-ketones was done with aq. NaOCl and a Cinchona alkaloid derivative as catalyst. A triphasic phase-transfer catalysis protocol has also been developed. p-Peptides have been used as catalysts in this reaction. ... 

Epoxidation. Conjugated carbonyl compounds are epoxidized with stoichiometric H2O2 and NaOH while employing tetrabutylammonium peroxydisulfate as catalysC... 

B.iii. Julia-Colonna Epoxidation. A new and useful innovation involving the hydroperoxide anion epoxidation of conjugated carbonyl compounds modified the procedure so the reaction is done in the... 

DFT calculations have been used to obtain mechanistic insights into the reaction of sulfur ylides PhHC (S+Me2) with dienals and enones by identifying all key transition states and intermediates along the reaction pathway for the 1,2-, 1,4-, and 1,6-nucleophilic attacks at PhCH=CHCH=CHCH=0 and for the 1,2- and 1,4-attacks at MeCH=CHCOMe. The final outcome of the reaction with both substrates has been found to be decided by the interplay between kinetic and thermodynamic factors. Thus, addition of a semi-stabilized ylide to conjugated carbonyl compounds prefers the 1,4-pathway under thermodynamic conditions, in consonance with the experimental reports. However, the formation of epoxides via a 1,2-addition pathway is equally competitive and could be favoured under kinetic conditions. The 2,3-trans cyclo-propanecarbaldehyde is the major product of the 1,4-addition pathway. The enone also prefers the 1,4-addition. ... 

Dimethylsulfonium methylide is both more reactive and less stable than dimethylsulfoxonium methylide, so it is generated and used at a lower temperature. A sharp distinction between the two ylides emerges in their reactions with a, ( -unsaturated carbonyl compounds. Dimethylsulfonium methylide yields epoxides, whereas dimethylsulfoxonium methylide reacts by conjugate addition and gives cyclopropanes (compare Entries 5 and 6 in Scheme 2.21). It appears that the reason for the difference lies in the relative rates of the two reactions available to the betaine intermediate (a) reversal to starting materials, or (b) intramolecular nucleophilic displacement.284 Presumably both reagents react most rapidly at the carbonyl group. In the case of dimethylsulfonium methylide the intramolecular displacement step is faster than the reverse of the addition, and epoxide formation takes place. 

Finally, chiral epoxides can be prepared from a,p-unsaturated carbonyl compounds through an entirely different approach, in which the epoxide oxygen is derived from the carbonyl moiety. For example, trans-aryl-vinyl epoxides 52 can be synthesized from conjugated aldehydes 50 and chiral sulfonium salts 51, with excellent ee s. The protocol is especially effective for substrates which bear a p-mcthoxy group on the aryl substituent <00TL7309>. 

Thiols may be enantioselectiveiy added in a conjugate fashion to a,p-unsaturated carbonyl compounds in the presence of chiral hydroxyamine catalysts e.g. chinchona alkaloids).242,244 249 252-261-269 In some cases ee of up to >80% were achieved e.g. Scheme 77).242-261-262 This methodology was utilized for the kinetic resolution of compound rat-86 Scheme 34) in a multigram scale.94 Related enantioselective 1,4-additions of thioacetates270-271 and selenophenols272 to enones are also known. Epoxidations, based on the asymmetric nucleophilic addition of peroxide anions to enones, are discussed separately.273... 

The two types of sulfur ylides also differ in their reactions with a,p-unsaturated carbonyl compounds. The highly reactive sulfonium ylides react rapidly by 1,2-addition across the carbon-oxygen double bond to yield the epoxides. On the other hand, the less reactive sulfoxonium ylides react by slower conjugate addition (1,4-addition) to give substituted ketocyclopropanes. Thus, dimethylsulfonium methylide (21) reacts rapidly with benzylideneacetophenone (chalcone) (37)... 

An interesting reaction for the synthesis of cyclopropanes makes use of a tungsten carbonyl compound as the electrophile <05JOC5852>. An initial conjugate addition of lithiated epoxide 101 onto tungsten carbonyl 102 leads to intermediate 103, which then does an intramolecular ring opening of the epoxide to provide cyclopropane 104. 

Reactions of chiral allylic boranes with carbonyl compounds Reactions of chiral allyl boranes with imines Asymmetric Addition of Carbon Nucleophiles to Ketones Addition of alkyl lithiums to ketones Asymmetric epoxidation with chiral sulfur ylids Asymmetric Nucleophilic Attack by Chiral Alcohols Deracemisation of arylpropionic acids Deracemisation of a-halo acids Asymmetric Conjugate Addition of Nitrogen Nucleophiles An asymmetric synthesis of thienamycin Asymmetric Protonation... 

An interesting alternative procedure for the generation of Darzens intermediates is illustrated in equation (26). In this method such anions are generated by the conjugate addition of a nucleophile to an activated alkene. In the presence of a carbonyl compound, an epoxide is formed. This process has been developed as an annulation procedure. 

Reductions Carbonyl compounds, including conjugated members, acid chlorides, azides, epoxides, and disulfides, are reduced. This salt (1) is a more selective reducing agent than tetrabutylammonium borohydride. 

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