Ethyl Knoevenagel condensation

Chromone-2-carbaldehyde, 3-methyl-synthesis, 3, 709 Chromonecarbaldehydes Knoevenagel condensation, 3, 711 Chromone-3-carbaldehydes mass spectra, 3, 615 oxidation, 3, 709 reactions, 3, 712 Schiff bases, 3, 712 synthesis, 3, 821 Chromone-2-carbonyl chloride Grignard reaction, 3, 711 Chromonecarboxamide, N-tetrazolyl-antiallergic activity, 3, 707 Chromone-2-carboxylic acid, 3-chloro-ethyl ester... 

An early application of this reaction to the preparation of barbiturates starts by the condensation of the ketone, I21, with ethyl cyanoacetate by Knoevenagel condensation. Alkylation of the product (122) with ethyl bromide by means of sodium ethoxide affords 123. Condensation of this intermediate with guanidine in the presence of sodium ethoxide gives the diimino analog of a barbiturate (124). Hydrolysis affords vinbarbital (111). > ... 

Both natural and non-natural compounds with a 2ff,5ff-pyrano[4,3-fc]pyran-5-one skeleton are of interest in medicinal chemistry. Several natural products, such as the pyripyropenes, incorporate this bicyclic ring system. The group of Beifuss has described an efficient microwave-promoted domino synthesis of the 2ff,5H-pyr-ano[4,3-fo]pyran-5-one skeleton by condensation of a,/3-unsaturated aldehydes with 4-hydroxy-6-methyl-2]-f-pyran-2-one (Scheme 6.244) [428]. It is assumed that in the presence of an amino acid catalyst a Knoevenagel condensation occurs first, which is then followed by a 6jr-electron electrocyclization to the pyran ring. While the conventional thermal protocol required a reaction time of up to 25 h (refluxing ethyl... 

A rapid and low cost preparation of the tiE, 5Z )-alkadienyl system encountered in several insect pheromones has been developed. Knoevenagel condensation of (T )-2-alkenals with ethyl hydrogen malonate in DMSO, in the presence... 

Because a base-catalyzed reaction involves the abstraction of a proton by the catalyst, one approach to measurement of the total number of basic sites and also the base strength distribution is to use the reactions of molecules with various values (96-100). For instance, the basic site distribution in calcined MgAl hy-drotalcites was determined by Corma et al. (99), who used the Knoevenagel condensation (Scheme 7) between benzaldehyde and methylene active compounds with various pKa values, i.e., ethyl cyanoacetate (pKa = 9), diethyl malonate (pKa = 13.3), and ethyl bromoacetate (pKa = 16.5). The authors found that this material has basic sites with pKa values up to 16.5, although most of the basic sites... 

An example of commercial interest is the synthesis of citronitrile (Scheme 17), a compound with a citrus-like odor, which is used in the cosmetics and fragrance industries. The first step in the synthesis of citronitrile is the Knoevenagel condensation of benzyl acetone and ethyl cyanoacetate. This condensation has been carried out with MgO and Al-Mg calcined hydrotalcites as catalysts (148). Similar results were obtained with the two solid catalysts, with yields of 75% of the Knoevenagel adduct. 

Ethyl E7E -2,4-dienoutes.1 These diunsaturaled esters can be prepared by Knoevenagel condensation (piperidine catalyzed) of ethyl 2-phenylsulfinylacetate with aldehydes and thermolysis of the product in the presence of potassium carbonate (equation I). 

Ethyl cyanoacetate in the presence of piperidine may also be used as the carbanionic component in reactions with salicylaldehyde. The initial Knoevenagel condensation is followed by a [l,7]-sigmatropic shift and cyclization to the 2-iminochromene derivative which adds another cyanoacetate molecule (67AP1). 

Keywords hydroxybenzaldehyde, ethyl acetate, Knoevenagel condensation, microwave irradiation, coumarin... 

Intramolecular cyclization. Knoevenagel condensation of diphenylacetaldehyde with diethyl malonate (piperidinium acetate catalysis) results in only a trace of the expected product when molecular sieves are present, the a-naphthol 1 is formed in 52% yield.2 A similar reaction is observed with ethyl acetoacetate and ethyl benzoylacetate. 

Further projects dealt with the fabrication of heterogeneous, basic or acidic solid-state catalysts or adsorbents carrying, for instance, amino or sulfonic acid groups. Amino-functionalized silicas were prepared and analyzed for the catalytic activity in Knoevenagel condensation reactions of aldehydes or ketones with ethyl cyanoace-tate ions by Macquarrie et al.154 155 Recently, Zhang et al.156,157 reported on the successful preparation of amino-functionalized silica thin films by means of the EISA approach. 

Hybrid organic/mineral solid base catalysts bearing primary and tertiary amino functions have been used as catalysts in the Knoevenagel condensation of benzaldehyde and ethyl cyanoacetate at 375 K in the presence of DMSO as solvent. Both catalysts exhibited a selectivity of approximately 100 % in ethyl trans-a-cyanocinnamate and could be recycled several times, after filtration and washing, without decrease in their catalytic performance.11711 The activity was found to be... 

The catalytic properties were checked in the transesterification of ethyl propionate with n-butanol and in the Knoevenagel condensation of benzaldehyde with ethyl cyanoacetate ... 

Excellent results were also obtained using activated hydrotalcite as a solid base catalyst in the Knoevenagel condensation of benzaldehyde with ethylcya-noacetate [110], ethylacetoacetate [111] or malononitrile [112] (see Fig. 2.34). Similarly, citronitrile, a perfumery compound with a citrus-like odor, was synthesized by hydrotalcite-catalyzed condensation of benzylacetone with ethyl-cyanoacetate, followed by hydrolysis and decarboxylation (Fig. 2.34) [113]. 

In contrast with the widespread application of zeolites as solid acid catalysts (see earlier), their use as solid base catalysts received scant attention until fairly recently [121]. This is probably because acid-catalyzed processes are much more common in the oil refining and petrochemical industries. Nonetheless, basic zeolites and related mesoporous molecular sieves can catalyze a variety of reactions, such as Knoevenagel condensations and Michael additions, which are key steps in the manufacture of flavors and fragrances, pharmaceuticals and other specialty chemicals [121]. Indeed, the Knoevenagel reaction of benzaldehyde with ethyl cyanoacetate (Fig. 2.36) has become a standard test reaction for solid base catalysts [121]. 

Cesium-exchanged zeolite X was used as a solid base catalyst in the Knoevenagel condensation of benzaldehyde or benzyl acetone with ethyl cyanoacetate [121]. The latter reaction is a key step in the synthesis of the fragrance molecule, citronitrile (see Fig. 2.37). However, reactivities were substantially lower than those observed with the more strongly basic hydrotalcite (see earlier). Similarly, Na-Y and Na-Beta catalyzed a variety of Michael additions [122] and K-Y and Cs-X were effective catalysts for the methylation of aniline and phenylaceto-nitrile with dimethyl carbonate or methanol, respectively (Fig. 2.37) [123]. These procedures constitute interesting green alternatives to classical alkylations using methyl halides or dimethyl sulfate in the presence of stoichiometric quantities of conventional bases such as caustic soda. 

Alkali-exchanged mesoporous molecular sieves are suitable solid base catalysts for the conversion of bulky molecules which cannot access the pores of zeolites. For example, Na- and Cs-exchanged MCM-41 were active catalysts for the Knoevenagel condensation of benzaldehyde with ethyl cyanoacetate (pKa=10.7) but low conversions were observed with the less acidic diethyl malonate (pKa=13.3) [123]. Similarly, Na-MCM-41 catalyzed the aldol condensation of several bulky ketones with benzaldehyde, including the example depicted in Fig. 2.38, in which a flavonone is obtained by subsequent intramolecular Michael-type addition [123]. 

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