Enolate anions, nitrile, reactions

Inductive and resonance stabilization of carbanions derived by proton abstraction from alkyl substituents a to the ring nitrogen in pyrazines and quinoxalines confers a degree of stability on these species comparable with that observed with enolate anions. The resultant carbanions undergo typical condensation reactions with a variety of electrophilic reagents such as aldehydes, ketones, nitriles, diazonium salts, etc., which makes them of considerable preparative importance. 

The alkylation reactions of enolate anions of both ketones and esters have been extensively utilized in synthesis. Both very stable enolates, such as those derived from (i-ketoesters, / -diketones, and malonate esters, as well as less stable enolates of monofunctional ketones, esters, nitriles, etc., are reactive. Many aspects of the relationships between reactivity, stereochemistry, and mechanism have been clarified. A starting point for the discussion of these reactions is the structure of the enolates. Because of the delocalized nature of enolates, an electrophile can attack either at oxygen or at carbon. 

Many types of carbonyl compounds, including aldehydes, ketones, esters, thioesters, acids, and amides, can be converted into enolate ions by reaction with LDA. Table 22.1 lists the approximate pKa values of different types of carbonyl compounds and shows how these values compare to other acidic substances we ve seen. Note that nitriles, too, are acidic and can be converted into enolate-like anions. 

C NMR studies of various heteroaromatic nitriles, including 1/7-1,2,3- and 2/7-1,2,3-triazolyl nitriles, reveal a correlation between a value derived from the chemical shifts, cn and c-cn and the reactivity of nitriles in forming the corresponding enaminoketones via reactions with the enolate anion of acetone. Based on the correlation, a new reactivity index y is proposed <82H(l9)22l>. 

The above system failed entirely when nonstabilized carbanions such as ketone or ester enolates or Grignard reagents were used as carbon nucleophiles, leading to reductive coupling of the anions rather than alkylation of the alkene. However, the fortuitous observation that the addition of HMPA to the reaction mixture prior to addition of the carbanion prevented this side reaction1 extended the range of useful carbanions substantially to include ketone and ester enolates, oxazoline anions, protected cyanohydrin anions, nitrile-stabilized anions3 and even phenyllithium (Scheme 3).s... 

Enolate anions generated from ketones, esters, and nitriles can be used as nucleophiles in Sn2 reactions. This results in the attachment of an alkyl group to the a-carbon in a process termed alkylation. Aldehydes are too reactive and cannot usually be alkylated in this manner. Alkylation of cyclohexanone is illustrated in the following equation ... 

Introduction of a cyano group a to the carbonyl group of a ketone can be accomplished by prior formation of the enolate anion with LDA in THF and addition of this solution to p-TsCN at —78°C. The products are formed in moderate to high yields but the reaction is not applicable to methyl ketones. Treatment of TMSCH2N(Me)C=Nf-Bu with iec-butylhthium and R2C=0, followed by iodo-methane and NaOMe leads to the nitrile, R2CH-CN. ... 

On reaction with Grignard reagents, p-keto nitriles are transformed into enamino ketones." The carbonyl group is protected as the enolate anion. To retain the nitrogen atom, a mild workup is required. 

In an extension of quinoline ring formation by reaction of enolate anions with o-trifluoromethylaniline, the enolate anion was replaced with anion of nitrile (44) to give quinoline (45) (Scheme 19) <94TL(35)7597). 

The synthesis begins with an Sn2 reaction (Chapter 10, Section 10.2) of bromide 141 with potassium cyanide to give 144. Note the use of the aprotic solvent DMF to facilitate the 8 2 reaction. A Grignard reaction of the nitrile with methylmagnesium bromide followed by hydrolysis leads to the requisite ketone (see Chapter 20, Section 20.9.3). The final step simply reacts the methyl ketone with LDA under kinetic control conditions to give the enolate anion (143), which is condensed with the ester (142) to give the diketone target, 140 (Section 22.7.2). 

Among the compounds capable of forming enolates, the alkylation of ketones has been most widely studied and applied synthetically. Similar reactions of esters, amides, and nitriles have also been developed. Alkylation of aldehyde enolates is not very common. One reason is that aldehydes are rapidly converted to aldol addition products by base. (See Chapter 2 for a discussion of this reaction.) Only when the enolate can be rapidly and quantitatively formed is aldol formation avoided. Success has been reported using potassium amide in liquid ammonia67 and potassium hydride in tetrahydrofuran.68 Alkylation via enamines or enamine anions provides a more general method for alkylation of aldehydes. These reactions are discussed in Section 1.3. 

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