Malonates, alkylation decarboxylation

Olefinic esters may be obtained directly by the Knoevenagel reaction. Alkyl hydrogen malonates are used in place of malonic acid. Decarboxylation then gives the ester directly as in the preparation of ethyl 2-heptenoate (78%) and methyl m-nitrocinnamate (87%). Alkyl hydrogen malonates are readily available by partial hydrolysis of dialkyl malonates. The use of malonic ester in the condensation leads to olefinic diesters, namely, alkylidenemalonates such as ethyl heptylidenemalonate (68%). A small amount of organic acid is added to the amine catalyst since the salts rather than the free amines have been shown to be the catalysts in condensations of this type. Various catalysts have been studied in the preparation of diethyl methylenemalonate. Increased yields are obtained in the presence of copper salts. Trimethylacetalde-hyde and malonic ester are condensed by acetic anhydride and zinc chloride. Acetic anhydride is also used for the condensation of furfural and malonic ester to furfurylidenemalonic ester (82%). ... 

A mixture of lupinine and epilupinine is obtainable by the following series of reactions. The betaine XXVI on cyclic hydrogenation and subsequent decarboxylation with 20 % hydrochloric acid gives a mixture of epimeric lupininic acids (XXIX). The dicarboxylic ester XXVIII is also obtained by the mercuric acetate dehydrogenation of the piperidine derivative XXX and by the alkylation of monomeric piperideine with a y-bromopropylmalonic ester. The last route is presumably a first Mannich condensation followed by an alkylation. Hydrolysis of the malonic esters, decarboxylation (XXIV), esterification, and reduction with lithium aluminum hydride complete the synthesis of a mixture which consists of 80% dZ-epilupinine and 20% dMupinine. Thermal... 

Combretazolone 22 was constructed via reaction of an appropriate a-hydroxyketone with PMB-isocyanate, subsequent cyclization and final removal of the PMB group in refluxing trifluoroacetic acid. Cyclopentenone analogues were prepared via sequential malonate alkylation-acylation followed by ring closure and decarboxylation. 

It has also been found that electron-withdrawing substituents facilitate the alkylative decarboxylation, whereas steric hindrance might retard the occurrence of such reaction. For example, diethyl and dimethyl disubstituted malonates do not practically undergo the decarboxylation when heated in DMS0/H20. ... 

The last-named reaction provides an excellent method for the preparation of a-substituted glutaric acids the intermediate alkyl (aryl) -2-cyanoethyl-malonate is both hydrolysed and decarboxylated re ily by boiling with an excess of 48 per cent, hydrobromic acid solution. 

One effective method for synthesis of tryptophan derivatives involves alkylation of formamido- or acetamido- malonate diesters by gramine[l,2]. Conversion to tryptophans is completed by hydrolysis and decarboxylation. These reactions were discussed in Chapter 12. An enolate of an a-nitro ester is an alternative nucleophile. The products can be converted to tryptophans by rcduction[3,4],... 

Converting the C 2 alkylated derivative to the corresponding malonic acid deriva tive by ester hydrolysis gives a compound susceptible to thermal decarboxylation Tern peratures of approximately 180°C are normally required... 

Section 21 7 The malonic ester synthesis is related to the acetoacetic ester synthesis Alkyl halides (RX) are converted to carboxylic acids of the type RCH2COOH by reaction with the enolate ion derived from diethyl mal onate followed by saponification and decarboxylation... 

The first ester function of the malonates is hydrolyzed much more easily than the second. This property can be used for synthesizing a large number of carboxyUc acids by alkylation or acylation of a malonate followed by hydrolysis and decarboxylation of one ester group. This is the case for ethyl... 

As actually carried out and reported in the chemical literature, diethyl malonate has been alkylated with 2-bromobutane in 83-84% yield and the product of that reaction converted to 3-methylpentanoic acid by saponification, acidification, and decarboxylation in 62-65% yield. ... 

C-alkylated material 119. The cyclization of a 3-aminopyridino-methylene malonate has been shown. The formation of amino-acrylate 121 was nearly quantitative and subsequent cyclization afforded a 50% yield of the 1,5-napthyridine. Saponification and decarboxylation gave the desired 1,5-napthyridine 124 in good yield. 

On heating with aqueous hydrochloric acid, the alkylated (or dialkylated) malonic ester undergoes hydrolysis of its two ester groups followed by decarboxylation (loss of C02) to yield a substituted monoacid. 

The malonic ester synthesis can also be used to prepare cydoalkane-carboxvlic acids. For example, when 1,4-dibromobutanc is treated with diethyl malonate in the presence of 2 equivalents of sodium ethoxide base, the second alkylation step occurs intrcunotecidariy to yield a cyclic product. Hydrolysis and decarboxylation then give cvclopentanecarboxylic acid. Three-, four-, five-. 

A more general method for preparation ofa-amino acids is the amidotnalmatesynthesis, a straightforward extension of the malonic ester synthesis (Section 22.7). The reaction begins with conversion of diethyl acetamidomalonate into an eno-late ion by treatment with base, followed by S 2 alkylation with a primary alkyl halide. Hydrolysis of both the amide protecting group and the esters occurs when the alkylated product is warmed with aqueous acid, and decarboxylation then takes place to vield an a-amino acid. For example aspartic acid can be prepared from, ethyl bromoacetate, BrCh CCHEt ... 

Malonic ester synthesis (Section 22.7) The synthesis of a carboxylic acid by alkylation of an alkyl halide, followed by-hydrolysis and decarboxylation. 

Diazotization of diethyl [(2-aminobenzoyl)[alkyl(or aryl)]amino]malonates 6 gives the cyclized products 7, which on treatment with sodium hydroxide in the cold undergo hydrolysis and partial decarboxylation to the acids 8. The latter afford l//-1.2,4-benzotriazepin-5(47/)-ones 9 when heated in xylene.347... 

Examples of this approach to the synthesis of ketones and carboxylic acids are presented in Scheme 1.4. In these procedures, an ester group is removed by hydrolysis and decarboxylation after the alkylation step. The malonate and acetoacetate carbanions are the synthetic equivalents of the simpler carbanions that lack the additional ester substituent. 

Similarly, the dilithium dianion of monoethyl malonate is easily alkylated and the product decarboxylates after acidification.50... 

With the A-ring unit readily available, we directed our attention to the formation of the B-ring. At first, we duplicated the five step scheme reported in Sih s strigol synthesis involving 1) esterification of the acid 14, 2) allylic bromination with N-bromo 8 ucc i n imi d e (NBS) to 15, 3) condensation with the sodium salt of dimethyl malonate to 16, 4) alkylation with methyl bromoacetate to 17, and 5) acid catalyzed hydrolysis and decarboxylation to the acid 18. 

Volume 75 concludes with six procedures for the preparation of valuable building blocks. The first, 6,7-DIHYDROCYCLOPENTA-l,3-DIOXIN-5(4H)-ONE, serves as an effective /3-keto vinyl cation equivalent when subjected to reductive and alkylative 1,3-carbonyl transpositions. 3-CYCLOPENTENE-l-CARBOXYLIC ACID, the second procedure in this series, is prepared via the reaction of dimethyl malonate and cis-l,4-dichloro-2-butene, followed by hydrolysis and decarboxylation. The use of tetrahaloarenes as diaryne equivalents for the potential construction of molecular belts, collars, and strips is demonstrated with the preparation of anti- and syn-l,4,5,8-TETRAHYDROANTHRACENE 1,4 5,8-DIEPOXIDES. Also of potential interest to the organic materials community is 8,8-DICYANOHEPTAFULVENE, prepared by the condensation of cycloheptatrienylium tetrafluoroborate with bromomalononitrile. The preparation of 2-PHENYL-l-PYRROLINE, an important heterocycle for the synthesis of a variety of alkaloids and pyrroloisoquinoline antidepressants, illustrates the utility of the inexpensive N-vinylpyrrolidin-2-one as an effective 3-aminopropyl carbanion equivalent. The final preparation in Volume 75, cis-4a(S), 8a(R)-PERHYDRO-6(2H)-ISOQUINOLINONES, il lustrates the conversion of quinine via oxidative degradation to meroquinene esters that are subsequently cyclized to N-acylated cis-perhydroisoquinolones and as such represent attractive building blocks now readily available in the pool of chiral substrates. 

Yet hands-on experience with 1 and other related compounds showed that free malonic acid groups on fullerenes are rather unstable even under physiological conditions and readily decarboxylate into side products, some of which may show toxicity under certain circumstances (Beuerle et al., 2007). To avoid these potential side effects new polar derivatives of 1 like 3, 4 and 5 have been synthesized (Beuerle et al., 2005 Witte et al., 2007). In these trisadducts the polar endgroups are attached via alkyl spacers to the fullerene core and thus no unwanted decarboxylation... 

With malonic esters and amides substituted at the central carbon, triazole formation is accompanied by decarboxylation and 4-alkyl-or 4-aryl-5-hydroxytriazoles are isolated. ... 

Acetone cyanohydrin nitrate, a reagent prepared from the nitration of acetone cyanohydrin with acetic anhydride-nitric acid, has been used for the alkaline nitration of alkyl-substituted malonate esters. In these reactions sodium hydride is used to form the carbanions of the malonate esters, which on reaction with acetone cyanohydrin nitrate form the corresponding nitromalonates. The use of a 100 % excess of sodium hydride in these reactions causes the nitromalonates to decompose by decarboxylation to the corresponding a-nitroesters. Alkyl-substituted acetoacetic acid esters behave in a similar way and have been used to synthesize a-nitroesters. Yields of a-nitroesters from both methods average 50-55 %. 

Relatively acidic carbon acids such as malonic esters and jS-keto esters were the first class of carbanions for which reliable conditions for alkylation were developed. The reason being that these carbanions are formed using easily accessible alkoxide ions. The preparation of 2-substiuted /i-kcto esters (entries 1, 4, and 8) and 2-substituted derivatives of malonic ester (entries 2 and 7) by the methods illustrated in Scheme 1.5 are useful for the synthesis of ketones and carboxylic acids, since both /1-ketoacids and malonic acids undergo facile decarboxylation ... 

Examples of this approach to the synthesis of ketones and carboxylic acids are presented in Scheme 1.6. In these procedures, an ester group is removed by hydrolysis and decarboxylation after the alkylation step. The malonate and acetoacetate carbanions are the synthetic equivalents of the simpler carbanions lacking the ester substituents. In the preparation of 2-heptanone (entries 1, Schemes 1.5 and 1.6), for example, ethyl acetoacetate functions as the synthetic equivalent of acetone. It is also possible to use the dilithium derivative of acetoacetic acid as the synthetic equivalent of acetone enolate.29 In this case, the hydrolysis step is unnecessary, and decarboxylation can be done directly on the alkylation product. 

The use of /i-ketocstcrs and malonic ester enolates has largely been supplanted by the development of the newer procedures based on selective enolate formation that permit direct alkylation of ketone and ester enolates and avoid the hydrolysis and decarboxylation of ketoesters intermediates. Most enolate alkylations are carried out by deprotonating the ketone under conditions that are appropriate for kinetic or thermodynamic control. Enolates can also be prepared from silyl enol ethers and by reduction of enones (see Section 1.3). Alkylation also can be carried out using silyl enol ethers by reaction with fluoride ion.31 Tetraalkylammonium fluoride salts in anhydrous solvents are normally the... 

The major advantages of this procedure over the enol sulfonate procedure lie in the availability of diethyl 2-chloro-2-cyclopropylethene-l,l-dicarboxylate from the corresponding acylmalonate and phosphorus oxychloride, and the fast, homogeneous, decarboxyl ative elimination reaction of the triethylamine salt of the half-ester in dry organic solvents. The conditions described here, with slight modifications (overnight treatment), have been used for a variety of g-chloro alkyl idene/aryl idene malonates as shown in Table I. 

Racemic jS-fluoroalkyl tyrosines and phenylalanines have been prepared by classical methods starting from the corresponding fluoroacetophenones. Synthesis of the nonracemic compounds is much more difficult, as exemplified by the preparation of jS-difluoromethyl meta-tyrosines (Figure 5.14). jS-Trifluoromethyl tryptophan is prepared by alkylation of ethyl acetamido malonate with indolyl-2,2-trifluoroethanol. Surprisingly, the decarboxylation reaction leads stereoselectively to the syn isomer (Figure 5.15). ... 

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