Ketone enolate anions, reaction with esters

As with ketone enolate anions (see 16-34), the use of amide bases under kinetic control conditions (strong base with a weak conjugate acid, aprotic solvents, low temperatures), allows the mixed Claisen condensation to proceed. Self-condensation of the lithium enolate with the parent ester is a problem when LDA is used as a base, ° but this is minimized with LICA (lithium isopropylcyclohexyl amide).Note that solvent-free Claisen condensation reactions have been reported. ° ... 

An ester enolate is formed by reaction with a strong base, and the resulting enolate anion can condense with an aldehyde, a ketone, or another ester. Ester enolates react with aldehydes or ketones to form P-hydroxy esters. Aldehyde or ketone enolate anions react with esters to form p-hydroxy esters, 1,3-diketones, or p-keto aldehydes. 

An ester enolate is formed by reaction with a strong base, and the resulting enolate anion can condense with an aldehyde, a ketone, or another ester. Ester enolates react with aldehydes or ketones to form p-hydroxy esters. Aldehyde or ketone enolate anions react with esters to form p-hydroxy esters, 1,3-diketones, or p-keto aldehydes 56,57,84,99,100,102,108,110,114,115. Enolate anions react as nucleophiles. They give nucleophilic acyl substitution reactions with acid derivatives. The condensation reaction of one ester with another is called a Claisen condensation and it generates a P-keto ester. A mixed Claisen condensation under thermodynamic conditions leads to a mixture of products, but kinetic control conditions can give a single product 52, 53, 54, 55, 59, 68, 69,98,99,101,125. 

The enolates of ketones can be acylated by esters and other acylating agents. The products of these reactions are [Tdicarbonyl compounds, which are rather acidic and can be alkylated by the procedures described in Section 1.2. Reaction of ketone enolates with formate esters gives a P-ketoaldehyde. As these compounds exist in the enol form, they are referred to as hydroxymethylene derivatives. Entries 1 and 2 in Scheme 2.16 are examples. Product formation is under thermodynamic control so the structure of the product can be predicted on the basis of the stability of the various possible product anions. 

The stability of the phosphonium-stabilized enolates also means that, although they react well with aldehydes, their reactions with ketones are often poor, and it is better in these cases to use phos-phonate-stabilized enolates. Being anionic, rather than neutral, these are more reactive. If an ester enolate equivalent is being used, the best base is the alkoxide ion belonging to the ester with a ketone enolate equivalent, use sodium hydride or an alkoxide. 

NaBHj/NiC or Raney nickel, the menthyloxy group is removed with NaBH /KOH to give 3,4-disubstituted butyrolactones with a high diastereo- and enantioselectivity (Figure 7.69). Corey and Houpis [1458] have described asymmetric Michael reactions of ketone enolates with a 2-thiophenyl crotonate of 8-phenmenthol. Chirality has also been introduced on the amino group of 2-ami-nomethyiacrylates to perform the asymmetric addition of the anion of the tert-Bu ester of cyclopentanecarboxylate [1459], More important developments have been reported with chiral a,p-unsaturated sulfoxides and nitro compounds as Michael acceptors (see below). 

The Wadsworth-Emmons condensation between the sodium enolate of the phosphono ester (21) and the 3 -ketone of 2, 5 -di-0-/ertbutyldimethylsilyladenosine gives (22) and (23). Reduction of the alkene (22) followed by reaction with the lithio anion of diethylmethylphosphonate gave (24). 

This chapter will discuss carbanion-like reactions that utilize enolate anions. The acid-base reactions used to form enolate anions will be discussed. Formation of enolate anions from aldehyde, ketones, and esters will lead to substitution reactions, acyl addition reactions, and acyl substitution reactions. Several classical named reactions that arise from these three fundamental reactions of enolate anions are presented. In addition, phosphonium salts wiU be prepared from alkyl halides and converted to ylids, which react with aldehydes or ketones to form alkenes. These ylids are treated as phosphorus-stabilized car-banions in terms of their reactivity. 

Even though ketones have the potential to react with themselves by aldol addition recall that the position of equilibrium for such reactions lies to the side of the starting materials (Section 18 9) On the other hand acylation of ketone enolates gives products (p keto esters or p diketones) that are converted to stabilized anions under the reaction conditions Consequently ketone acylation is observed to the exclusion of aldol addition when ketones are treated with base m the presence of esters... 

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. 

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. 

The mixed Claisen condensation of two different esters is similar to the mixed aldol condensation of two different aldehydes or ketones (Section 23.5). Mixed Claisen reactions are successful only when one of the two ester components has no a hydrogens and thus can t form an enolate ion. For example, ethyl benzoate and ethyl formate can t form enolate ions and thus can t serve as donors. They can, however, act as the electrophilic acceptor components in reactions with other ester anions to give mixed /3-keto ester products. 

In the presence of a strong base, the ot carbon of a carboxylic ester can condense with the carbonyl carbon of an aldehyde or ketone to give a P-hydroxy ester, which may or may not be dehydrated to the a,P-unsaturated ester. This reaction is sometimes called the Claisen reaction,an unfortunate usage since that name is more firmly connected to 10-118. In a modem example of how the reaction is used, addition of tert-butyl acetate to LDA in hexane at -78°C gives the lithium salt of ferf-butyl acetate, " (12-21) an enolate anion. Subsequent reaction a ketone provides a simple rapid alternative to the Reformatsky reaction (16-31) as a means of preparing P-hydroxy erf-butyl esters. It is also possible for the a carbon of an aldehyde or ketone to add to the carbonyl carbon of a carboxylic ester, but this is a different reaction (10-119) involving nucleophilic substitution and not addition to a C=0 bond. It can, however, be a side reaction if the aldehyde or ketone has an a hydrogen. 

An enolate anion generated from a carboxylic acid derivative may be used in the same sorts of nucleophilic reactions that we have seen with aldehyde and ketone systems. It should be noted, however, that the base used to generate the enolate anion must be chosen carefully. If sodium hydroxide were used, then hydrolysis of the carboxylic derivative to the acid (see Section 7.9.2) would compete with enolate anion formation. However, the problem is avoided by using the same base, e.g. ethoxide, as is present in the ester... 

Now let us look at the ease of forming the enolate anion nucleophiles. Ketones are more acidic than esters (see Section 10.7). Taken together, these factors mean the more favoured product is going to be the P-diketone (acetylacetone), formed from a ketone nucleophile by a Claisen reaction with an ester. This is the reaction observed. 

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 ... 

There are certain difficulties in achieving this type of aldol reaction. First, alkali-induced ester hydrolysis would compete with addition. Second, a Claisen condensation of the ester might intervene, and third, the ester anion is a stronger base than the enolate anions of either aldehydes or ketones, which means reaction could be defeated by proton transfer of the type... 

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