Alkylation, enolate ions synthesis

Section 21 7 The malonic ester synthesis is related to the acetoacetic ester synthesis Alkyl halides (RX) are converted to carboxylic acids of the type RCH2COOH by reaction with the enolate ion derived from diethyl mal onate followed by saponification and decarboxylation... 

Both the malonic ester synthesis and the acetoacetic ester synthesis are easy to cany out because they involve unusually acidic dicarbonyi compounds. As a result, relatively mild bases such as sodium ethoxide in ethanol as solvent can be used to prepare the necessary enolate ions. Alternatively, however, it s also possible in many cases to directly alkylate the a position of monocarbonyl compounds. A strong, stericaliy hindered base such as LDA is needed so that complete conversion to the enolate ion takes place rather than a nucleophilic addition, and a nonprotic solvent must be used. 

Alpha hydrogen atoms of carbonyl compounds are weakly acidic and can be removed by strong bases, such as lithium diisopropylamide (LDA), to yield nucleophilic enolate ions. The most important reaction of enolate ions is their Sn2 alkylation with alkyl halides. The malonic ester synthesis converts an alkyl halide into a carboxylic acid with the addition of two carbon atoms. Similarly, the acetoacetic ester synthesis converts an alkyl halide into a methyl ketone. In addition, many carbonyl compounds, including ketones, esters, and nitriles, can be directly alkylated by treatment with LDA and an alkyl halide. 

Still another possibility in the base-catalyzed reactions of carbonyl compounds is alkylation or similar reaction at the oxygen atom. This is the predominant reaction of phenoxide ion, of course, but for enolates with less resonance stabilization it is exceptional and requires special conditions. Even phenolates react at carbon when the reagent is carbon dioxide, but this may be due merely to the instability of the alternative carbonic half ester. The association of enolate ions with a proton is evidently not very different from the association with metallic cations. Although the equilibrium mixture is about 92 % ketone, the sodium derivative of acetoacetic ester reacts with acetic acid in cold petroleum ether to give the enol. The Perkin ring closure reaction, which depends on C-alkylation, gives the alternative O-alkylation only when it is applied to the synthesis of a four membered ring ... 

In particular the synthesis of an a-alkylaldehyde or branched chain ketone by this overall strategy is of considerable merit since some of the problems associated with the a-alkylation of an enolate ion are largely avoided (e.g. competing aldol condensation in the case of an aldehyde, or polyalkylation and low regio-selective alkylation in the case of a ketone). 

In the malonic ester synthesis this enolate ion is alkylated in the same manner as in the acetoacetic ester synthesis. Saponification of the alkylated diester produces a diacid. The carbonyl group of either of the acid groups is at the /3-position relative to the other acid group. Therefore, when the diacid is heated, carbon dioxide is lost in the same manner as in the acetoacetic ester synthesis. The difference is that the product is a carboxylic acid in the malonic ester synthesis rather than the methyl ketone that is produced in the acetoacetic ester synthesis. The loss of carbon dioxide from a substituted malonic acid to produce a monoacid is illustrated in the following equation ... 

In both the acetoacetic ester synthesis and the malonic ester synthesis, it is possible to add two different alkyl groups to the a-carbon in sequential steps. First the enolate ion is generated by reaction with sodium ethoxide and alkylated. Then the enolate ion of the alkylated product is generated by reaction with a second equivalent of sodium ethoxide, and that anion is alkylated with another alkyl halide. An example is provided by the following equation ... 

Q Show how enols, enolate ions, and enamines act as nucleophiles. Predict the products of their reactions with halogens, alkyl halides, and other electrophiles. Show how they are useful in synthesis. 

Many alkylation and acylation reactions are most effective using anions of /3-dicarbonyl compounds that can be completely deprotonated and converted to their enolate ions by common bases such as alkoxide ions. The malonic ester synthesis and the acetoacetic ester synthesis use the enhanced acidity of the a protons in malonic ester and acetoacetic ester to accomplish alkylations and acylations that are difficult or impossible with simple esters. 

The acetoacetic ester synthesis is similar to the malonic ester synthesis, but the final products are ketones specifically, substituted derivatives of acetone. In the acetoacetic ester synthesis, substituents are added to the enolate ion of ethyl acetoacetate (acetoacetic ester), followed by hydrolysis and decarboxylation to produce an alkylated derivative of acetone. 

Alkylation of enolate ions (Section 22.8) (a) Malonic ester synthesis... 

The most general method of preparation for a amino acids is the amido-malonate synthesis, a straightforward extension of the malonic ester synthesis (Section 22.8). The reaction begins with conversion of diethyl acetamidomalonate into an enolate ion by treatment with base, followed by Sf 2 alkylation with a primary alkyl halide. Hydrolysis of both the amidel protecting group and the esters occurs when the alkylated product is warmed 1 with aqueous acid, and decarboxylation then takes place to yield an a-amiaOj acid. For example, aspartic acid can be prepared from ethyl bromoacetate ... 

Alkylations of enolate ions to introduce alkyl groups to carbons adjacent to a carbonyl group (e.g., acetoacetic ester synthesis, malonic ester synthesis)... 

Alkylation of Enolate Ions 855 Problem 22.12 How could you use a malonic ester synthesis to prepare the following compound ... 

A discussion of approaches to the stereoselective synthesis of 3-(dichlorovinyl)-2,2-dirrethylcyclapraparie carboxylic acid through intramolecular alkylation of an enolate ion is presented. Principles for achieving good control of the relative stereochemistry about the cyclopropane ring will be described. The control of the absolute stereochemistry on the ring was accomplished through the use of a chiral enolate. 

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