Enolate anions Michael addition

In the late nineteenth century, Michael found that the enolate anion (46) derived from diethyl malonate reacts with ethyl acrylate at the P-carbon (as shown in the illustration) to give an enolate anion, 47, as the product. Remember from Chapter 22 (Section 22.7.4) that the a-proton of a 1,3-dicarbonyl compound such as diethyl malonate is rather acidic (pK of about 11), and even a relatively weak base will deprotonate to form the enolate anion. Michael addition of 46 with ethyl acrylate will give enolate anion 47, and aqueous acid workup leads to the isolated product, 48. Attack at the -carbon is possible because that carbon is less hindered than the acyl carbon, so reaction at the C=C unit is somewhat faster than attack at the acyl carbon. Michael addition occurs with relatively stable carbanion nucleophiles, such as malonate derivative 46 and some other common nucleophiles. Other conjugated carbonyl derivatives react similarly. 

Stabilized anions exhibit a pronounced tendency to undergo conjugate addition to a p unsaturated carbonyl compounds This reaction called the Michael reaction has been described for anions derived from p diketones m Section 18 13 The enolates of ethyl acetoacetate and diethyl malonate also undergo Michael addition to the p carbon atom of a p unsaturated aldehydes ketones and esters For example... 

The 1,4-addition of an enolate anion 1 to an o ,/3-unsaturated carbonyl compound 2, to yield a 1,5-dicarbonyl compound 3, is a powerful method for the formation of carbon-carbon bonds, and is called the Michael reaction or Michael addition The 1,4-addition to an o ,/3-unsaturated carbonyl substrate is also called a conjugate addition. Various other 1,4-additions are known, and sometimes referred to as Michael-like additions. 

Few a-ketosulphoxides 123 were prepared by trapping the enolate anions 124, which are generated by the Michael addition of Grignard reagents to easily available a, jS-unsaturated carbonyl compounds 125, with methanesulphinyl chloride174 (equation 65). 

Vinyl sulfones, being good Michael acceptors, have been regarded as useful reagents for carbon-carbon bond formation. Nucleophiles used often are organometallic reagents, enamines and enolate anions and the Michael addition products are usually obtained in... 

Domino transformations combining two consecutive anionic steps exist in several variants, but the majority of these reactions is initiated by a Michael addition [1]. Due to the attack of a nucleophile at the 4-position of usually an enone, a reactive enolate is formed which can easily be trapped in a second anionic reaction by, for example, another n,(5-urisalurated carbonyl compound, an aldehyde, a ketone, an inline, an ester, or an alkyl halide (Scheme 2.1). Accordingly, numerous examples of Michael/Michael, Michael/aldol, Michael/Dieckmann, as well as Michael/SN-type sequences have been found in the literature. These reactions can be considered as very reliable domino processes, and are undoubtedly of great value to today s synthetic chemist... 

Yosikoshi reported the synthesis of furan derivatives by the reaction of 1,3-diketones with nitroalkenes, in which the Michael addition of the anions of 1,3-diketones and the subsequent intramolecular displacement of the nitro group by enolate oxygen are involved as key steps (Eq. 7.40).42... 

Main group organometallic polymerization catalysts, particularly of groups 1 and 2, generally operate via anionic mechanisms, but the similarities with truly coordinative initiators justify their inclusion here. Both anionic and coordinative polymerization mechanisms are believed to involve enolate active sites, (Scheme 6), with the propagation step akin to a 1,4-Michael addition reaction. 

Deprotection of 2,2-disubstituted-l,3-dithiolanes to give carbonyl compounds can be achieved using Oxone with KBr in aq. MeCN <06TL8559> and a review of silylated heterocycles as formyl anion equivalents includes reference to 64 <06CC4881>. A method for transformation of propargylic dithiolanes 43 into tetrasubstituted furans has been reported <06SL1209> and Michael addition of enolates to the chiral dithiolane dioxide 65 takes place... 

The conjugate addition of enolate anions onto a,P-unsaturated systems is an important synthetic reaction, and is termed the Michael reaction, though this terminology may often be used in the broader... 

The reaction is considered as a combination of a Michael reaction, the conjugate addition of an enolate anion on to an unsaturated carbonyl compound, plus an aldol reaction followed by elimination of water. 

Michael reaction conjugate addition of enolate anion onto unsaturated carbonyl... 

Michael-type addition of an enolate anion to an alkynyliodonium salt probably produces the unstable iodonium ylide 34 34a. Loss of Phi from... 

Conjugate addition of enolate anion to a, b-unsaturated carbonyl compounds is known as Michael addition. 

Michael addition of a dithiane anion 20, generated from the dithiane 19 with butyllithium, to the butenolide 21 creates the enolate 22 which has been efficiently alkylated in situ by 3,4,5-trimethoxybenzyl chloride to give 24 (mp 146-146.5 °C) in 65% overall yield. Protona-tion of 22 furnished the Michael adduct 23, which again can be deprotonated16 with LDA at — 78 °C to give 22 and alkylated (trimethoxybenzyl chloride, THF, HMPA, 3 h at — 78 °C, 18 h at 20 °C) to yield 24. Both variants are equally completely diastereoselective giving rise to the trans- product. 

The reaction sequence depicted i.e., the in situ alkylation of an a-anion created by Michael addition, is an important method for the formation of an enolate of an unsaturated carbonyl compound17,18. 

Electrophiles that have been used for the second alkylation of this tandem Michael addition -alkylation sequence are limited to primary iodoalkanes, (bromomethyl)benzenes and 3-bromo-propenes. Tables 9 and 10 provide details of the alkylations of enolate species prepared by 1,4-additions of -a,/j-unsaturated iron-acyl complexes by anionic carbon nucleophiles and anionic nitrogen nucleophiles, respectively. 

A total synthesis of ( )-aromatin has utilized the lithium anion of the dithiane of (E)-2-methyl-2-butenal as a functional equivalent of the thermodynamic enolate of methyl ethyl ketone in an aprotic Michael addition (Scheme 189) (81JOC825). Reaction of the lithium anion (805) with 2-methyl-2-cyclopentenone followed by alkylation of the ketone enolate as its copper salt with allyl bromide delivered (807). Ozonolysis afforded a tricarbonyl which cyclized with alkali to the aldol product (808). Additional steps utilizing conventional chemistry converted (808) into ( )-aromatin (809). 

Nitroalkenes, e.g. 1 -nitrocyclohexene, 1-nitrocycloheptene, 1-nitrocyclooctene and (3-methyl-j8-nitrostyrene, undergo Michael addition with the enolate anions of (3-ketoesters. The resulting acids undergo a Nef reaction to give 1,4-diketones, which yield furans by subsequent ring closure (Scheme 18) (59LA(626)7l). 

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