Carboxylic acid ester dianions

Initiation of heterocyclic carbon-carbon bond fission by potassium anions Generation of carboxylic acid ester dianions from p-lactones... 

Nitroalkenes react with lithium dianions of carboxylic acids or with hthium enolates at -100 °C, and subsequent treatment of the Michael adducts with aqueous acid gives y-keto acids or esters in a one-pot operation, respectively (Eq. 4.52).66 The sequence of Michael addition to nitroalkenes and Nef reaction (Section 6.1) provides a useful tool for organic synthesis. For example, the addition of carbanions derived from sulfones to nitroalkenes followed by the Nef reaction and elimination of the sulfonyl group gives a,P-unsaturated ketones (Eq. 4.53).67... 

Formally related reactions are observed when anthracene [210] or arylole-fines [211-213] are reduced in the presence of carboxylic acid derivatives such as anhydrides, esters, amides, or nitriles. Under these conditions, mono- or diacylated compounds are obtained. It is interesting to note that the yield of acylated products largely depends on the counterion of the reduced hydrocarbon species. It is especially high when lithium is used, which is supposed to prevent hydrodimerization of the carboxylic acid by ion-pair formation. In contrast to alkylation, acylation is assumed to prefer an Sn2 mechanism. However, it is not clear if the radical anion or the dianion are the reactive species. The addition of nitriles is usually followed by hydrolysis of the resulting ketimines [211-213]. 

Enolate hydroxylation is a problem of long standing. Direct oxygenation succeeds with the fully substituted enolates of certain a,a-disubstituted ketones and a variety of carboxylic acid derivatives (ester anions, acid dianions, amide anions), but the reaction of enolates, RCH = C(0 )R or CH2 = C(0 )R, with oxygen results in complex products of overoxidation. The stable... 

Carboxylic acids can be alkylated in the a position by conversion of their salts to dianions [which actually have the enolate structures RCH=C(0 )21497] by treatment with a strong base such as lithium diisopropylamide.1498 The use of Li as the counterion is important, because it increases the solubility of the dianionic salt. The reaction has been applied1499 to primary alkyl, allylic, and benzylic halides, and to carboxylic acids of the form RCHjCOOH and RR"CHCOOH.1454 This method, which is an example of the alkylation of a dianion at its more nucleophilic position (see p. 368), is an alternative to the malonic ester synthesis (0-94) as a means of preparing carboxylic acids and has the advantage that acids of the form RR R"CCOOH can also be prepared. In a related reaction, methylated aromatic acids can be alkylated at the methyl group by a similar procedure.1500... 

We have previously seen (0-96) that dianions of carboxylic acids can be alkylated in the a position. These ions can also be acylated on treatment with a carboxylic ester1705 to give salts of p-keto acids. As in 0-96, the carboxylic acid can be of the form RCH2COOH or RR"CHCOOH. Since p-keto acids are so easily converted to ketones (2-40), this is also a method for the preparation of ketones R COCHiR and R COCHRR", where R can be primary, secondary, or tertiary alkyl, or aryl. If the ester is ethyl formate, an a-formyl carboxylate salt (R = H) is formed, which on acidification spontaneously de-carboxylates into an aldehyde.1706 This is a method, therefore, for achieving the conversion RCH2COOH — RCH2CHO, and as such is an alternative to the reduction methods discussed in 0-83. When the carboxylic acid is of the form RR CHCOOH. better yields are obtained by acylating with acyl halides rather than esters.1707... 

On the pages which follow, general methods are illustrated for the synthesis of a wide variety of classes of organic compounds including acyl isocyanates (from amides and oxalyl chloride p. 16), epoxides (from reductive coupling of aromatic aldehydes by hexamethylphosphorous triamide p. 31), a-fluoro acids (from 1-alkenes p. 37), 0-lactams (from olefins and chlorosulfonyl isocyanate p. 51), 1 y3,5-triketones (from dianions of 1,3-diketones and esters p. 57), sulfinate esters (from disulfides, alcohols, and lead tetraacetate p. 62), carboxylic acids (from carbonylation of alcohols or olefins via carbonium-ion intermediates p. 72), sulfoxides (from sulfides and sodium periodate p. 78), carbazoles... 

The conjugate addition of unstabilized enolates to various acceptors was conceptually recognized by early researchers however, complications were encountered depending on the enolates and acceptors employed. Reexamination of this strategy was made possible by the development of techniques for kinetic enolate formation. This discussion is divided into three enolate classes (a) aldehyde and ketone enolates, azaenolates or equivalents, (b) ester and amide enolates, dithioenolates and dienolates and (c) a,0-carboxylic dianions and a-nitrile anions, in order to emphasize the differential reactivity of various enolates with various acceptors."7 The a-nitrile anions are included because of their equivalence to the hypothetical a-carboxylic acid anion. 

N. Petragnani, M. Yonashiro, The Reactions of Dianions of Carboxylic Acids and Ester Enolates , Synthesis 1982, 521. 

The a-chloro-a-sultinyl ketone 20 was prepared from methyl benzoate and chloromethyl phenyl sulfoxide 19 after in situ a-lithiation. Compound 20 is dimetallated by KH and f-BuLi to give the keto dianion 21, which is converted into a potassium/lithium ynolate 22 (equation 7). The resulting metal ynolates are converted into thioesters, carboxylic acids, amides and esters (Section V). 

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