Enolate anions, malonate, reaction with

In Chapter 22 (Section 22.7.4), malonate derivatives were easily converted to the corresponding enolate anion, and reaction with alkyl halides or other electrophilic species gave the C3-alkylated product. Indeed, if 102 is treated with sodium metal (or NaH, LDA, etc.), enolate anion 103 is formed it reacts with an alkyl halide such as benzyl bromide (PhCH2Br) to give 104. If 104 is heated with aqueous sodium hydroxide and then treated with aqueous HCI, phthalic acid (35) and the amino acid phenylalanine (57) are formed as the final products. 

There are two classical reaction sequences in organic chemistry that rely on enolate alkylation. One is the malonic ester synthesis.61 jjj synthetic example taken from the Clive and Hisaindee synthesis of brevioxime,62 diethyl malonate was treated with a base such as sodium ethoxide, under thermodynamic control conditions. The resulting enolate anion is treated with the indicated alkyl halide to give the alkylated product 81 (in 72% yield).Saponification of 81 to the dicarboxylic acid (82, in 99% yield), was followed by decarboxylation (sec. 2.9.D) and formation of the substituted acid 83, in 94% yield. ... 

Under ordinary conditions, aryl or alkenyl halides do not react with enolate anions, although reaction can occur with aryl halides bearing strongly electronegative substituents in the ortho and para positions. 2,4-Dinitrochlorobenzene, for example, with ethyl cyanoacetate gives ethyl (2,4-dinitrophenyl)cyanoacetate (90%) by an addition-elimination pathway. Unactivated aryl halides may react with enolates under more vigorous conditions, particularly sodium amide in liquid ammonia. Under these conditions, the reaction of bromobenzene with diethyl-malonate, for example, takes place by an elimination-addition sequence in which benzyne is an intermediate (1.8). 

Malonic esters can be converted to the enolate anion and condensed with aldehydes, ketones, or acid derivatives. The reaction of malonic acid with an aldehyde using pyridine as a base is called the Knoevenagel condensation. 

The intra-molecular Claisen condensation is called a Dieckmann condensation, and it generates a cyclic compound 58,99,101,118. Malonic esters can be converted to the enolate anion and condensed with aldehydes, ketones, or add derivatives. The reaction of malonic acid with an aldehyde using pyridine as a base is called the Knoevenagel condensation 59, 60, 61, 62, 69, 99,108,110,112, 113,119,124. 

In subsequent studies, the scope of the Heck reaction/ anion-trapping cascade was further extended using soft car-banionic nucleophiles as illustrated in the asymmetric synthesis of (—)-D -capnellene 17. Treatment of prochiral vinyl triflate 15 with Pd(OAc>2, (5)-BINAP, and NaBr, as weU as the sodium enolate of diethyl (2-((rert-butyldiphe-nylsilyl)oxy)ethyl)malonate, gave the cyclic product 16 in 87% ee and 77% yield as the sole product. The use of NaBr as an additive improved the optical yields and was critical in preventing counteranion exchange between the triflate anion and the enolate anion by complexing with sodium enolate (Scheme 13.6). Compound 16 was then advanced through several steps to complete the total synthesis (—)-D -capnellene 17. 

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 ... 

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,... 

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... 

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 . 

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 reactions of the lithium enolate of diethyl 2-[(diphenylmethylene)amino]malonate with several alkynyliodonium triflates are rare examples of enolate alkynylations with iodonium species other than the ethynyl(phenyl)- and (phenylethynyl)phenyliodonium ions (equation 125)16. Two experimental protocols were followed, i.e. addition of the enolates to the iodonium salts and vice versa, the former procedure giving higher yields of alkynylmalonates. As with other enolate alkynylations, these reactions are thought to involve alkylidenecarbene intermediates. It has been proposed, however, that the carbenes rearrange with migration of the diethyl 2-[(diphenyl) amino] malonate anion 16. 

In both the acetoacetic ester synthesis and the malonic ester synthesis, it is possible to add two different alkyl groups to the a-carbon in sequential steps. First the enolate ion is generated by reaction with sodium ethoxide and alkylated. Then the enolate ion of the alkylated product is generated by reaction with a second equivalent of sodium ethoxide, and that anion is alkylated with another alkyl halide. An example is provided by the following equation ... 

Nitro-l-(phenylsulfonyl)-l//-indole 829 undergoes nucleophilic addition reactions with enolates of diethyl malonate and cyclohexanone, lithium dimethylcuprate (Scheme 159), and indole anion (Equation 209) to afford the corresponding 3-substituted 2-nitroindoles in low to high yields <1997TL5603, 1999TL7615>. 

In many of these cases, both the enolate anion and substrate can exist as (Z) or (E) isomers. With enolates derived from ketones or carboxylic esters. The (E) enolates gave the syn pair of enantiomers (p. 166), while (Z) enolates gave the anti pair. Nitro compounds add to conjugated ketones in the presence of a dipeptide and a piperazine. ° Malonate derivatives also add to conjugated ketones, and keto esters add to conjugated esters.Addition of chiral additives to the reaction, such as metal-salen complexes,proline derivatives, or (—)-sparteine, ... 

The step marked with an asterisk is reversible and, in fact, is an unfavorable equilibrium, because the product (a simple ketone enolate) is a less stable anion than is the doubly stabilized malonate anion. However, the next step, reaction with more malonic ester to make a new malonate anion, drives the equilibrium to product. The reaction is catalytic in base because malonate is regenerated in this last step. 

The ylide from (97) reacted with llV-desmethyIdiazepam (35) in a one-pot reaction to give (98) in 50% yield (Equation (3)). This is a variation on the more usual reaction in which the lactam is converted into an enol phosphate, for example, by reaction with sodium hydride and dimorpholinophosphonic chloride, which is then reacted with the anion of dimethyl malonate <93JHC945>. 

Diaryliodonium salts have found synthetic application as arylating reagents in reactions with various organic substrates under polar, catalytic, or photochemical conditions. Typical examples of arylations of nucleophiles under polar, non-catalytic conditions are shown in Scheme 3.271 and include the reactions of diaryliodonium salts with thiosulfonate anions 675 [861], fluoride anion [862,863], malonates 676 [864] and silyl enol ethers 677 [865]. 

Nucleophilic additions to the carbon-carbon double bond of ketene dithioacetal monoxides have been reported [84-86]. These substrates are efficient Michael acceptors in the reaction with enamines, sodium enolates derived from P-dicarbonyl compounds, and lithium enolates from simple ester systems. Hydrolysis of the initiEil products then led to substituted 1,4-dicarbonyl systems [84]. Alternatively, the initial product carbanion could be quenched with electrophiles [85]. For example, the anion derived from dimethyl malonate (86) was added to the ketene dithioacetal monoxide (87). Regioselective electrophilic addition led to the product (88) in 97% overall yield (Scheme 5.28). The application of this methodology to the synthesis of rethrolones [87] and prostaglandin precursors [88] has been demonstrated. Recently, Walkup and Boatman noted the resistance of endocyclic ketene dithioacetals to nucleophilic attack [89]. 

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. 

Aqueous acid workup of 92 gives the alcohol, 93. With malonic ester derivatives, loss of water to form 94 occurs very easily, with dilute acid or with gentle heating because the C=C unit is conjugated to two carbonyl groups, facilitating dehydration. Although it is possible to isolate 83, it is more usually difficult. The enolate anion of malonate esters also reacts with ketones and may be condensed with other esters in acyl substitution reactions. When 90 is treated with NaOEt in ethanol and then with ethyl butanoate, the final product after mild hydrolysis is a keto-diester, 95. 

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. 

A p-keto ester can be hydrolyzed to a P-keto acid, and heating leads to decarboxylation. Malonic acid derivatives, as well as P-ketone acids decarboxylate upon heating 63,109, 111, 135. Enolate anions react with alkyl halides by an S]v2 reaction to give alkylated carbonyl compounds 65, 67, 70, 84, 108, 116, 127,... 

In the late nineteenth century, Michael found that the enolate anion (46) derived from diethyl malonate reacts with ethyl acrylate at the P-carbon (as shown in the illustration) to give an enolate anion, 47, as the product. Remember from Chapter 22 (Section 22.7.4) that the a-proton of a 1,3-dicarbonyl compound such as diethyl malonate is rather acidic (pK of about 11), and even a relatively weak base will deprotonate to form the enolate anion. Michael addition of 46 with ethyl acrylate will give enolate anion 47, and aqueous acid workup leads to the isolated product, 48. Attack at the -carbon is possible because that carbon is less hindered than the acyl carbon, so reaction at the C=C unit is somewhat faster than attack at the acyl carbon. Michael addition occurs with relatively stable carbanion nucleophiles, such as malonate derivative 46 and some other common nucleophiles. Other conjugated carbonyl derivatives react similarly. 

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