Ketones Knoevenagel condensation

The term Knoevenagel Condensation was originally applied to the base-catalysed condensation of the carbonyl ( CO) group of aldehydes and ketones with the reactive methylene group of malonic acid, with loss of w ater ... 

Reactions. The chemical properties of cyanoacetates ate quite similar to those of the malonates. The carbonyl activity of the ester function is increased by the cyano group s tendency to withdraw electrons. Therefore, amidation with ammonia [7664-41-7] to cyanoacetamide [107-91-5] (55) or with urea to cyanoacetylurea [448-98-2] (56) proceeds very easily. An interesting reaction of cyanoacetic acid is the Knoevenagel condensation with aldehydes followed by decarboxylation which leads to substituted acrylonitriles (57) such as (29), or with ketones followed by decarboxylation with a shift of the double bond to give P,y-unsaturated nitriles (58) such as (30) when cyclohexanone [108-94-1] is used. 

The first step in the Gewald reaction is a Knoevenagel condensation of an activated nitrile with a ketone or aldehyde to produce an acrylonitrile 8, which is then thiolated at the methylene position with elemental sulfur. The sulfurated compound 9 initially decays... 

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). > ... 

Another publication is the Index of Reviews in Organic Chemistry , complied by Lewis, Chemical Society, London, a classified listing of review articles. The first volume, published in 1971, lists reviews from 1960 (in some cases much earlier) to 1970 in alphabetical order of topic. Thus four reviews are listed under Knoevenagel condensation , five under Inclusion compounds , and one under Vinyl ketones. There is no index. A second volume (1977) covers the literature to 1976. Annual or biannual supplements appeared from 1979 until the publication was terminated in 1985. Classified lists of review articles on organometallic chemistry are found in articles by Smith and Walton and by Bruce.A similar list for heterocyclic chemistry is found in articles by Katritzky and others.See also the discussion of the Index of Scientific Reviews, page 1638. 

Condensation between carboxylic esters and aldehydes or ketones Condensation between active-hydrogen compounds and aldehydes or ketones (Knoevenagel)... 

As the name implies, the first step of this domino process consists of a Knoevenagel condensation of an aldehyde or a ketone 2-742 with a 1,3-dicarbonyl compound 2-743 in the presence of catalytic amounts of a weak base such as ethylene diammonium diacetate (EDDA) or piperidinium acetate (Scheme 2.163). In the reaction, a 1,3-oxabutadiene 2-744 is formed as intermediate, which undergoes an inter- or an intramolecular hetero-Diels-Alder reaction either with an enol ether or an alkene to give a dihydropyran 2-745. 

Other valuable substrates for the domino Knoevenagel/hetero-Diels-Alder reaction are chiral oxathiolanes such as 2-778, which are easily accessible by condensation of 2-thioacetic acid and a ketone in the presence ofpTsOH, followed by oxidation with hydrogen peroxide [390]. As described by Tietze and coworkers, the Knoevenagel condensation of 2-778 with aldehydes as 2-777 can be performed in... 

The domino process probably involves the chiral enamine intermediate 2-817 formed by reaction of ketone 2-813 with 2-815. With regard to the subsequent cy-doaddition step of 2-817 with the Knoevenagel condensation product 2-816, it is interesting to note that only a normal Diels-Alder process operates with the 1,3-bu-tadiene moiety in 2-817 and not a hetero-Diels-Alder reaction with the 1-oxa-l,3-butadiene moiety in 2-816. The formed spirocydic ketones 2-818/2-819 can be used in natural products synthesis and in medidnal chemistry [410]. They have also been used in the preparation of exotic amino adds these were used to modify the physical properties and biological activities of peptides, peptidomimetics, and proteins... 

Song A, Wang X, Lam KS (2003) A convenient synthesis of coumarin-3-carboxylic acids via Knoevenagel condensation of Meldrum s acid with ortho-hydroxyaryl aldehydes or ketones. Tetrahedron Lett 44 1755-1758... 

TiIV compounds also work well at promoting cross-aldol reactions between two different aldehydes and/or ketones without prior activation or protection (Scheme 19).74 Claisen condensation and Knoevenagel condensation are promoted by TiX4, an amine, and trimethylsilyl triflate.75-77... 

Scheme 6.177 a-Methylenation of ketones [335], lactam formation from lactones [336], urea formation [337], and Knoevenagel condensation [338, 478]. 

Knoevenagel condensation of diethyl malonate or related compounds with a,fi-unsaturated aldehydes and ketones results in diene esters (equation 40)78. This condensation reaction has been used to extend the polyene chain length of vitamin A related compounds (equations 4179 and 4280). 

The stereoselective total synthesis of both ( )-corynantheidine (61) (170,171) (alio stereoisomer) and ( )-dihydrocorynantheine (172) (normal stereoisomer) has been elaborated by Szdntay and co-workers. The key intermediate leading to both alkaloids was the alio cyanoacetic ester derivative 315, which was obtained from the previously prepared ketone 312 (173) by the Knoevenagel condensation accompanied by complete epimerization at C-20 and by subsequent stereoselective sodium borohydride reduction. ( )-Corynantheidine was prepared by modification of the cyanoacetate side chain esterification furnished diester 316, which underwent selective lithium aluminum hydride reduction. The resulting sodium enolate of the a-formyl ester was finally methylated to racemic corynantheidine (171). 

Treatment of the /3-keto ester 220 with sodium ethoxide at elevated temperature triggered off an epoxide ring opening by / -elimination that was followed by the desired Knoevenagel condensation to afford the tricyclic product 206 (Scheme 34). The enone moiety in the intermediate 221 did not show a propensity for deprotonation and, therefore, the ketone carbonyl function of the enone moiety was available for a Knoevenagel condensation. The reduction of the p-keto ester (206) to the corresponding diol was the next objective. Treatment of the TES-protected -keto ester (TES-206) with DIBAH afforded the diastereomeric diols 222 and 223 in a moderate diastereoselec-tivity in favour of the undesired diastereomer 222. The diastereomers were separated and the undesired diastereomer 222 was epimerized to 223 by a sequence that consists of Mitsunobu inversion and benzoate ester reduction [98, 99]. 

The condensation of aldehydes and ketones with active hydrogen atoms is called Knoevenagel condensation. It is related to an aldol condensation and commonly is used to produce enones (a compound with a carbon-carbon double bond adjacent to a carbonyl). The process requires a weak base (an amine). A typical excimple and mechanism eire presented in Figure 15-22. 

Knoevenagel Condensation A condensation of an aldehyde or ketone with a molecule containing an active methylene in the presence of an amine or ammonia. 

In the last decade, the mesoporous molecular sieve MCM-41 has been developed (2S2) and applied as a catalyst to many acid-catalyzed reactions (2SS). However, until now, comparatively few investigations of mesoporous molecular sieves as base catalysts have been reported (169,211-214,234,235). For example, sodium- and cesium-exchanged mesoporous MCM-41 were shown to be mildly selective, water-stable, recyclable catalysts for the base-catalyzed Knoevenagel condensation, and mesoporous MCM-41 containing intraporous cesium oxide particles prepared by impregnation with aqueous cesium acetate and subsequent calcination was found to have strong-base activity for the Michael addition (211,213) and rearrangement of co-phenylalkanals to phenyl alkyl ketones (212). 

Base catalysis is one of the less-well developed areas of heterogeneous catalysis. We have developed novel bases derived from amines via the one-step process outlined above. A range of supported amines have been prepared and evaluated in a series of reactions We have also investigated the nature of the amine groups attached to the surface in comparison with those formed by grafting onto pre-formed silica. While many workers have studied the use of basic catalysts for the Knoevenagel condensation of aldehydes, with three articles on the use of MCM derivatives[ 12], little has been done on the more demanding condensation of ketones. 

A convenient synthesis of lonchocarpin (206) and similar compounds is the Knoevenagel condensation of a 6-acetylchromene (207) with benzaldehyde (7iJCS(C)796, 71JCS(C)8U>. Carbonyl groups present in chromenes as aldehydes or ketones form oximes and 2,4-dinitrophenylhydrazones <77HC(31)11). 

Most C,H-acidic compounds can be condensed with aldehydes or ketones to yield alkenes. Some of these reactions have also been realized on insoluble supports, with either the C,H-acidic (nucleophilic) reactant or the electrophilic reactant linked to the support. Some illustrative examples are listed in Table 5.6. Polystyrene-bound malonic esters or amides, cyanoacetamides, nitroacetic ester [95], and 3-oxo esters undergo Knoevenagel condensation with aromatic or aliphatic aldehydes. Catalytic amounts of piperidine and heating are generally required, although reactive substrates can react at room temperature. 

Keywords ketone, aldehyde, dicyanomethane, benzyltriethylammonium chloride, Knoevenagel condensation... 

Keywords aldehyde, ketone, active methylene compound, Knoevenagel condensation, basic alumina, microwave irradiation, olefin... 

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. 

The enolate A or the nitronate A, respectively, initially adds to the C=0 double bond of the aldehyde or the ketone. The primary product in both cases is an atkoxide, D, which contains a fairly strong C,H acid, namely, of an active-methylene compound or of a nitroalkane, respectively. Hence, intermediate D is protonated at the atkoxide oxygen and the C-fi atom is deprotonated to about the same extent as in the case of the respective starting materials. An OH-substituted enolate C is formed (Figures 13.52 and 13.53), which then undergoes an Elcb elimination, leading to the condensation product B. The Knoevenagel condensation and the aldol condensation have in common that both reactions consist of a sequence of an enolate hydroxy alkylation and an Elcb elimination. 

For a number of processes, reactive distillation is not possible, as some of the reactants are destroyed or degraded in side reactions by heating them up to boiling temperature. Examples of such processes are the Knoevenagel-condensation of aldehydes or ketones with components of high CH-acidity, the production of enam-ines or carbonic acid amides, or the esterification of fatty acids with fatty alcohols to fatty esters [7]. 

The phenanthrenequinone oxime 54 was built in four steps from the two benzenoid precursors 52 and 53. Beckmann rearrangement of 54 furnished the cyano-acid 55. The latter, after reduction to the corresponding cyano-aldehyde, was homologated by Knoevenagel condensation with malonic acid to give, after reduction, hydrolysis and esterification, the diester 56. This compound underwent Dieckmann condensation, installing the seven-membered C-7 ketone 57 in 69% yield after hydrolysis and decarboxylation of the intermediate (3-ketoester. 

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