Carbanions from acetoacetic ester

The synthetic utility of alkylation of enolates is utilized in the syntheses of malonic ester (3.3) and acetoacetic ester (3.2). For example, carbanion generated from malonic ester undergoes an Sn2 reaction with alkyl halide to yield alkyl-substituted malonic ester. The monosubstituted malonic ester still has an active hydrogen atom. The second alkyl group (same or different) can be introduced in a similar manner. Acid-catalyzed hydrolysis or base-catalyzed hydrolysis of mono- or disubstituted derivative of malonic ester followed by acidification gives the corresponding mono- or disubstituted malonic acid, which on decarboxylation yields the corresponding monocarboxylic acid (Scheme 3.3). 

Of the very many alkylation methods that have been developed, we can look at only a few first, two classics of organic synthesis, the malonic ester synthesis and the acetoacetic ester synthesis and then, several newer methods. In doing this we shall be concerned not only with learning a bit more about how to make new molecules from old ones, but also with seeing the variety of ways in which carbanion chemistry is involved. 

By the malonic ester and acetoacetic ester we make a-substituted acids and a-substituted ketones. But why not do the job directly 1 Why not convert simple acids (or esters) and ketones into their carbanions, and allow these to react with alkyl halides There are a number of obstacles (a) self-condensation—aldol condensation, for example, of ketones (b) polyalkylation and (c) for unsym-metrical ketones, alkylation at both a-carbons, or at the wrong one. Consider self-condensation. A carbanion can be generated from, say, a simple ketone but competing with attack on an alkyl halide is attack at the carbonyl carbon of another ketone molecule. What is needed is a base-solvent combination that can convert the ketone rapidly and essentially completely into the carbanion before appreciable self-condensation can occur. Steps toward solving this problem have been taken, and there are available methods—so far, of limited applicability— for the direct alkylation of acids and ketones. 

Acetone cyanohydrin nitrate, a reagent prepared from the nitration of acetone cyanohydrin with acetic anhydride-nitric acid, has been used for the alkaline nitration of alkyl-substituted malonate esters. In these reactions sodium hydride is used to form the carbanions of the malonate esters, which on reaction with acetone cyanohydrin nitrate form the corresponding nitromalonates. The use of a 100 % excess of sodium hydride in these reactions causes the nitromalonates to decompose by decarboxylation to the corresponding a-nitroesters. Alkyl-substituted acetoacetic acid esters behave in a similar way and have been used to synthesize a-nitroesters. Yields of a-nitroesters from both methods average 50-55 %. 

The fe-carbanions derived from alkyl acetoacetates 17a-e add on the A2-imidazolinium cation 3a to form adduct imidazolidines 18a-e, which could not be obtained in a pure state and were isolated as tautomeric enaminoketoesters 19a e (82TL3301, 83H2129, 85T3345). The formation of homologous enaminoketo-ester 20 from 15 and the fe-carbanion of ethyl acetoacetate 17a is also reported (91T4155). 

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