Anions malonate enolates

Deprotonation of methylene groups containing two electron-withdrawing alkoxycarbonyl groups with an appropriate base easily converts them into their corresponding enolate anions. These enolate anions are able to attack carbon electrophiles to form new C —C bonds. One of the important applications of this reaction is to construct small carbocyclic rings, in particular cyclobutanes. For example, intermolecular condensation of l,3-dibromo-2,2-dimethylpropane (1) and the dipotassium salt of diethyl malonate (2) gives diethyl 3,3-dimethylcyclobutane-l,l-dicarboxylate (3).18... 

The reaction of diethyl malonate (90) with sodium hydride generates enolate anion 91 as the conjugate base, and hydrogen gas is the conjugate acid. It has the three resonance contributors shown in the illustration, although 91A has the highest concentration of electron density, and 91 will react as a carbanion nucleophile. There is one extra resonance form in the malonate enolate anion relative to a simple ester due to the second carbonyl unit, and it means that 91 is more stable than the enolate derived from a monoester. In part, this accounts for the enhanced acidity and easier formation of the enolate anion using a weaker base. Once formed, 91 is a carbon nucleophile and it will react with both aldehydes and ketones, as well as with other esters. 

Rather than pyridine or ammonia, bases such as sodium hydride or sodium ethoxide can be used to generate a malonate enolate anion. Such enolates are easier to control, from a synthetic viewpoint, and allow a wider range of reactions. For this reason, they are collected into this section. An example is the reaction of the sodium enolate of diethyl 2-methylmalonate with the bromine moiety in phthalimide derivative 4.42. This displacement reaction was followed by removal of the phthalimidoyl group, hydrolysis of the esters and decarboxylation to give 2-methyl-6-aminohexanoic acid (4.4J),23 Phthalimide 4.42 was prepared by reaction of 1,4-dibromobutane with potassium phthalimide.23 The length of the carbon chain in the... 

Stabilized anions exhibit a pronounced tendency to undergo conjugate addition to a p unsaturated carbonyl compounds This reaction called the Michael reaction has been described for anions derived from p diketones m Section 18 13 The enolates of ethyl acetoacetate and diethyl malonate also undergo Michael addition to the p carbon atom of a p unsaturated aldehydes ketones and esters For example... 

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 ... 

Stable enolates such as diethyl malonate anions react with allyl sulfones (or acetates) in the presence of nickel complexes to give a mixture of the a- and /-product83. The regioselectivity is generally poor in the nickel-catalyzed reaction, but the molybdenum-catalyzed reaction is selective for alkylation at the more substituted allylic site, thereby creating a quaternary carbon center84. 

The decarboxylation reaction usually proceeds from the dissociated form of a carboxyl group. As a result, the primary reaction intermediate is more or less a carbanion-like species. In one case, the carbanion is stabilized by the adjacent carbonyl group to form an enolate intermediate as seen in the case of decarboxylation of malonic acid and tropic acid derivatives. In the other case, the anion is stabilized by the aid of the thiazolium ring of TPP. This is the case of transketolases. The formation of carbanion equivalents is essentially important in the synthetic chemistry no matter what methods one takes, i.e., enzymatic or ordinary chemical. They undergo C—C bond-forming reactions with carbonyl compounds as well as a number of reactions with electrophiles, such as protonation, Michael-type addition, substitution with pyrophosphate and halides and so on. In this context,... 

Acyl imidazolides are more reactive than esters but not as reactive as acyl halides. Entry 7 is an example of formation of a (3-ketoesters by reaction of magnesium enolate monoalkyl malonate ester by an imidazolide. Acyl imidazolides also are used for acylation of ester enolates and nitromethane anion, as illustrated by Entries 8, 9, and 10. (V-Methoxy-lV-methylamides are also useful for acylation of ester enolates. 

When a catalytic amount of base is used, the most effective nucleophiles are enolates derived from relatively acidic compounds such as (J-ketoesters or malonate esters. The adduct anions are more basic than the nucleophile and are protonated under the... 

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... 

The mechanistic steps can be deduced by inspection of structures and conditions. Enolate anion formation from diethyl malonate under basic conditions is indicated, and that this must attack the epoxide in an Sn2 reaction is implicated by the addition of the malonate moiety and disappearance of the epoxide. The subsequent ring formation follows logically from the addition anion, and is analogous to base hydrolysis of an ester. Ester hydrolysis followed by decarboxylation of the P-keto acid is then implicated by the acidic conditions and structural relationships. 

Dicarbonyl donors bearing a thioester has been applied in the Mannich reaction to A -tosyl imines. Ricci presented an enantioselective decarboxylative addition of malonic half thioester 37 to imine 38. In the Mannich-type addition, catalyst 36 deprotonates the malonic acid thioester followed by decarboxylation to generate a stabilized thioacetate enolate. This stabilized anion reacts with facial selectivity to the imine due to steric-tuning from 36 [47] (Scheme 8). 

Diethyl malonate has been proposed for use as a proton source in these cyclization reactions [124], It is not a sufficiently strong acid to protonate the radical-anion rapidly. However it irreversibly protonates the enol intermediate generated after carbon-caibon bond formation. In one case, control of stereochemistry in favour of the traHS-sunstituted five membered ring 39 was achieved by the addition of cerium(Ill) ions [124],... 

Anions derived from malonates are ambident nucleophiles, which can react at the carbon or oxygen atom. Therefore, carbon-carbon bond-forming reactions by alkylation or acylation of enolates have been encountered with difficulties. Side reactions which may cause problems are the above-mentioned competiting O-reaction and dialkylation . 

By analogy, the chemical Claisen condensation using the enolate anion from diethyl malonate in Figure 2.10 proceeds much more favourably than that using the enolate from ethyl acetate. The same acetoacetic acid product can be formed in the malonate condensation by hydrolysis of the acylated malonate intermediate and decarboxylation of the gem-diacid. 

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