Decarboxylation, ketoester malonic acid

One such compound, bropirimine (112), is described as an agent which has both antineo-plastic and antiviral activity. The first step in the preparation involves formation of the dianion 108 from the half ester of malonic acid by treatment with butyllithium. Acylation of the anion with benzoyl chloride proceeds at the more nucleophilic carbon anion to give 109. This tricarbonyl compound decarboxylates on acidification to give the beta ketoester 110. Condensation with guanidine leads to the pyrimidone 111. Bromination with N-bromosuccinimide gives bropirimine (112) [24]. 

The phenanthrenequinone oxime 54 was built in four steps from the two benzenoid precursors 52 and 53. Beckmann rearrangement of 54 furnished the cyano-acid 55. The latter, after reduction to the corresponding cyano-aldehyde, was homologated by Knoevenagel condensation with malonic acid to give, after reduction, hydrolysis and esterification, the diester 56. This compound underwent Dieckmann condensation, installing the seven-membered C-7 ketone 57 in 69% yield after hydrolysis and decarboxylation of the intermediate (3-ketoester. 

Figure 2.56 collects some exemplary reactions of Ceo with different bromoma-lonates and other applicable keto compounds. This collection shows that there is virtually no Umit to the choice of side chains, which renders the Bingel-Hirsch reaction an attractive and flexible starting point for the synthesis of fuUerene-containing materials. For example, the base-mediated conversion of a malonate and Cao into the respective methanofullerene can also be achieved. With the semiester of malonic acid instead of a malonate, the monosubstituted methanofullerene is obtained because the primary product is instantaneously decarboxylated (Figure 2.56). P-Ketoesters may also be reacted under Bingel-Hirsch conditions to give methanofuUerenes.

Several reviews have been written which cover the history of the Krapcho reaction through 1982.1,4 Further research in this area revealed the application of the decarboxylation method to compounds such as P-ketoesters, malonate esters, a-cyanoester, and a-sulfonylesters. The classical method for decarboxylation of these compounds usually involves acidic or basic hydrolysis, followed by thermal decarboxylation. Unfortunately, compounds containing acid or base sensitive functional groups are not compatible with these methods. Modem Krapcho conditions have replaced cyanide with less toxic halide anions. Additionally, several decarboxylations have occurred in the absence of salt.4... 

The malonic ester synthesis might seem like an arcane technique that only an organic chemist would use. Still, it is much like the method that cells use to synthesize the long-chain fatty acids found in fats, oils, waxes, and cell membranes. Figure 22-4 outlines the steps that take place in the lengthening of a fatty acid chain by two carbon atoms at a time. The growing acid derivative (acyl-CoA) is activated as its thioester with coenzyme A (structure on page 1027). A malonic ester acylation adds two of the three carbons of malonic acid (as malonyl-CoA), with the third carbon lost in the decarboxylation. A )8-ketoester results. Reduction of the ketone, followed by dehydration and reduction of... 

Relatively acidic carbon acids such as malonate esters and )8-ketoesters were the first class of carbanions for which reliable conditions for alkylation were developed. The reason for this was that these carbanions are formed by easily accessible alkoxide ions. The preparation of 2-substituted j8-ketoesters (entries 1, 4, and 8) and 2-substituted derivatives of malonic ester (entries 2 and 7) by the methods illustrated in Scheme 1.4 is useful for the synthesis of ketones and carboxylic acids. Both jS-ketoacids and malonic acids undergo facile decarboxylation ... 

Fig. 13.65. Acylation of various malonic diester or malonic half-ester enolates with carboxylic acid chlorides. Spontaneous decarboxylation of the acylation products to furnish /3-ketoesters (see variants 1 and 2) and transformation of the acylation products into /3-ketoesters by way of alcoholysis/decarboxylation (see variant 3).

Although the acetoacetic ester synthesis and the malonic ester synthesis are used to prepare ketones and carboxylic acids, the same alkylation, without the hydrolysis and decarboxylation steps, can be employed to prepare substituted /3-ketoesters and /3-diesters. In fact, any compound with two anion stabilizing groups on the same carbon can be deprotonated and then alkylated by the same general procedure. Several examples are shown in the following equations. The first example shows the alkylation of a /3-ketoester. Close examination shows the similarity of the starting material to ethyl acetoacetate. Although sodium hydride is used as a base in this example, sodium ethoxide could also be employed. 

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