Esters, enolate anions alkylation

Enolate Initiators. In principle, ester enolate anions should represent the ideal initiators for anionic polymeri2ation of alkyl methacrylates. Although general procedures have been developed for the preparation of a variety of alkaU metal enolate salts, many of these compounds are unstable except at low temperatures (67,102,103). Usehil initiating systems for acrylate polymeri2ation have been prepared from complexes of ester enolates with alkak metal alkoxides (104,105). 

Thus the reactions of cyclic or acyclic enamines with acrylic esters or acrylonitrile can be directed to the exclusive formation of monoalkylated ketones (3,294-301). The corresponding enolate anion alkylations lead preferentially to di- or higher-alkylation products. However, by proper choice of reaction conditions, enamines can also be used for the preferential formation of higher alkylation products, if these are desired. Such reactions are valuable in the a substitution of aldehydes, which undergo self-condensation in base-catalyzed reactions (117,118). Monoalkylation products are favored in nonhydroxylic solvents such as benzene or dioxane, whereas dialkylation products can be obtained in hydroxylic solvents such as methanol. The difference in products can be ascribed to the differing fates of an initially formed zwitterionic intermediate. Collapse to a cyclobutane takes place in a nonprotonic solvent, whereas protonation on the newly introduced substitutent and deprotonation of the imonium salt, in alcohol, leads to a new enamine available for further substitution. 

A variation of the malonic ester synthetic uses a P-keto ester such as 116. In Section 22.7.1, the Claisen condensation generated P-keto esters via acyl substitution that employed ester enolate anions. When 116 is converted to the enolate anion with NaOEt in ethanol, reaction with benzyl bromide gives the alkylation product 117. When 117 is saponified, the product is P-keto acid 118, and decarboxylation via heating leads to 4-phenyl-2-butanone, 119. This reaction sequence converts a P-keto ester, available from the ester precursors, to a substituted ketone in what is known as the acetoacetic acid synthesis. Both the malonic ester synthesis and the acetoacetic acid synthesis employ enolate alkylation reactions to build larger molecules from smaller ones, and they are quite useful in synthesis. 

Enolate anion alkylations, acetoacetic ester synthesis and malonic ester synthesis (Sections 19.6 and 19.7). 

Ester enolates of alkyl isobutyrates are models of the growth center in the anionic polymerization of MMA. Lochmaim et prepared several alkyl a-lithioisobutyrates as models... 

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. 

The reactive species is the corresponding enolate-anion 4 of malonic ester 1. The anion can be obtained by deprotonation with a base it is stabilized by resonance. The alkylation step with an alkyl halide 2 proceeds by a Sn2 reaction ... 

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. 

Domino transformations combining two consecutive anionic steps exist in several variants, but the majority of these reactions is initiated by a Michael addition [1]. Due to the attack of a nucleophile at the 4-position of usually an enone, a reactive enolate is formed which can easily be trapped in a second anionic reaction by, for example, another n,(5-urisalurated carbonyl compound, an aldehyde, a ketone, an inline, an ester, or an alkyl halide (Scheme 2.1). Accordingly, numerous examples of Michael/Michael, Michael/aldol, Michael/Dieckmann, as well as Michael/SN-type sequences have been found in the literature. These reactions can be considered as very reliable domino processes, and are undoubtedly of great value to today s synthetic chemist... 

Diethyl malonate can be converted into its enolate anion, which may then be used to participate in an Sn2 reaction with an alkyl halide (see Section 10.7). Ester hydrolysis and mild heating leads to production... 

Undesirable intermolecular reactions can be avoided during certain synthetic conversions. Thus it is often useful to carry out C-alkylation and C-acylation of compounds that form enolate anions, for example, esters with a-hydrogens. Such reactions are often complicated by self-condensation since the enolate anion can attack the carbonyl group of a second ester molecule. Attachment of the enolizable ester to a polymer support at low loading levels allows the alkylation and acylation reactions (Eq. 9-79) to be performed under... 

The anions of esters such as ethyl 3-oxobutanoate and diethyl propanedioate can be alkylated with alkyl halides. These reactions are important for the synthesis of carboxylic acids and ketones and are similar in character to the alkylation of ketones discussed previously (Section 17-4A). The ester is converted by a strong base to the enolate anion, Equation 18-18, which then is alkylated in an SN2 reaction with the alkyl halide, Equation 18-19. Usually, C-alkylation predominates ... 

While the addition-oxidation and the addition-protonation procedures are successful with ester enol-ates as well as more reactive carbon nucleophiles, the addition-acylation procedure requires more reactive anions and the addition of a polar aptotic solvent (HMPA has been used) to disfavor reversal of anion addition. Under these conditions, cyano-stabilized anions and ester enolates fail (simple alkylation of the carbanion) but cyanohydrin acetal anions are successful. The addition of the cyanohydrin acetal anion (71) to [(l,4-dimethoxynaphthalene)Cr(CO)3] occurs by kinetic control at C-P in THF-HMPA and leads to the a,p-diacetyl derivative (72) after methyl iodide addition, and hydrolysis of the cyanohydrin acetal (equation 50).84,124-126... 

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 ... 

Alkylation of the enolate anion derived from ethyl acetoacetate followed by removal of the ester group is known as the acetoacetic ester synthesis and is an excellent method for the preparation of methyl ketones. The product of an acetoacetic ester synthesis is the same as the product that would be produced by the addition of the same... 

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. 

Looking back on the history of ketone dianion chemistry, one soon notices that dianion species, derived from / -keto esters, have been in continuous steady use in organic synthesis3,4, as shown in Scheme 2. Thus, ethyl acetoacetate can be converted to the corresponding ketone o a -chainon via consecutive proton abstraction reactions. The resulting dienolate anion reacts with a variety of alkyl halides to give products, resulting from exclusive attack at the terminal enolate anions. 

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