Halides, alkyl reaction with carbanions

Some examples of the more important alkylation reactions with relatively acidic carbon acids are included in the reactions shown in Scheme 1.4. These reactions are important means of synthesizing a variety of ketones, carboxylic acids, and related compounds, as illustrated in Scheme 1.5. These reactions share a common mechanism involving base-catalyzed formation of a carbanion followed by nucleophilic attack via an Sn2 mechanism. The alkylating agent must be a suitable substrate for an Sn2 reaction. Primary halides and sulfonates are the best substrates. Secondary systems usually give poorer yields because of competition from elimination... 

The thenyl cyanides are of great importance for the preparation of thiophene derivatives. Because of the acidifying effects of both the thienyl and of the cyano groups, carbanions are easily obtained through the reaction with sodamide or sodium ethoxide, which can be alkylated with halides, carbethoxylated with ethyl carbonate, or acylated by Claisen condensation with ethyl... 

Mechanistically the reaction can be divided into two steps. Initially the alkyl halide 1 reacts with sodium to give an organometallic species 3, that can be isolated in many cases. In a second step the carbanionic R of the organometallic compound 3 acts as nucleophile in a substitution reaction with alkyl halide 1 to replace the halide ... 

Olefination Reactions Involving Phosphonate Anions. An important complement to the Wittig reaction involves the reaction of phosphonate carbanions with carbonyl compounds 253 The alkylphosphonic acid esters are made by the reaction of an alkyl halide, preferably primary, with a phosphite ester. Phosphonate carbanions are generated by treating alkylphosphonate esters with a base such as sodium hydride, n-butyllithium, or sodium ethoxide. Alumina coated with KF or KOH has also found use as the base.254... 

Where a reagent is starred, the star indicates the atom that accepts electrons from, or donates electrons to, the substrate as the case may be. No clear distinction can necessarily be made between what constitutes a reagent and what a substrate, for though N02, OH, etc., are normally thought of as reagents, the carbanion (41) could, at will, be either reagent or substrate, when reacted with, for example, an alkyl halide. The reaction of the former on the latter is a nucleophilic attack, while that of the latter on the former would be looked upon as an electrophilic attack but no matter from which reactant s standpoint a reaction is viewed, its essential nature is not for a moment in doubt. 

Here too, a second alkylation can be made to take place yielding RC=CR or R C=CR. It should, however, be remembered that the above carbanions—particularly the acetylide anion (57)—are the anions of very weak acids, and are thus themselves strong bases, as well as powerful nucleophiles. They can thus induce elimination (p. 260) as well as displacement, and reaction with tertiary halides is often found to result in alkene formation to the exclusion of alkylation. 

The most important reactions of alkyl substituents a and y to the ring heteroatom are those which proceed via base-catalyzed deprotonation. Treatment of 2- and 4-alkyl heterocycles with strong bases such as sodamide and liquid ammonia, alkyllithiums, LDA, etc., results in an essentially quantitative deprotonation and formation of the corresponding carbanions. These then react normally with a wide range of electrophiles such as alkyl halides and tosylates, acyl halides, carbon dioxide, aldehydes, ketones, formal-dehyde/dimethylamine, etc., to give the expected condensation products. Typical examples of these transformations are shown in Scheme 17. Deprotonation of alkyl groups by the use of either aqueous or alcoholic bases can also be readily demonstrated by NMR spectroscopy, and while the amount of deprotonation under these conditions is normally very small, under the appropriate conditions condensations with electrophiles proceed normally (Scheme 18). 

The 3-methylene group of l-methoxy-2-oxindole (163) is easily ionized to give a carbanion that undergoes well-known types of reactions with alkyl halides or activated olefins without loss of the methoxyl group (e.g. 

Finally, acetylide anions have been alkylated with propargyl halides to give excellent yields of dialkynes643,644. Similar reactions have been used in the synthesis of a wide variety of natural products including lactones and macrolides645,646 and leukotrienes647-651. With many halides, reaction with acetylide anions is not useful however, due to elimination side-reactions caused by the significant basicity of the carbanion. 

Functional groups are often converted to alkoxides, carbanions, or other strong nucleophiles by deprotonation or reaction with a strong nucleophile. Then the carbanion or other strong nucleophile reacts with a weak electrophile such as a carbonyl group or an alkyl halide. 

Among common carbon-carbon bond formation reactions involving carbanionic species, the nucleophilic substitution of alkyl halides with active methylene compounds in the presence of a base, e. g., malonic and acetoacetic ester syntheses, is one of the most well documented important methods in organic synthesis. Ketone enolates and protected ones such as vinyl silyl ethers are also versatile nucleophiles for the reaction with various electrophiles including alkyl halides. On the other hand, for the reaction of aryl halides with such nucleophiles to proceed, photostimulation or addition of transition metal catalysts or promoters is usually required, unless the halides are activated by strong electron-withdrawing substituents [7]. Of the metal species, palladium has proved to be especially useful, while copper may also be used in some reactions [81. Thus, aryl halides can react with a variety of substrates having acidic C-H bonds under palladium catalysis. 

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