Aldehydes Knoevenagel reaction

Knoevenagel reaction. The condensation of an aldehyde with an active methylene compound (usually malonic acid or its derivatives) in the presence of a base is generally called the Knoevenagel reaction. Knoevenagel found that condensations between aldehydes and malonic acid are effectively catalysed by ammonia and by primary and secondary amines in alcoholic solution of the organic amines piperidine was regarded as the best catalyst. 

The Doebner condensation (or reaction) is a slight modification of the Knoevenagel reaction and consists in warming a solution of the aldehyde and... 

Examples of the Knoevenagel reaction with aldehydes are given under crotonic acid (111,145), P-n-hexylacrylic acid (111,144), sorbic acid (111,145) and furylacryUc acid (V,10). 

Knoevenagel reaction is the synthesis of a, p-unsaturated acids by reaction of aldehydes and compounds with active methylene groups in the presence of an organic base... 

The prototype of a Knoevenagel reaction shown in the scheme above is the condensation of an aldehyde or ketone 1 with a malonic ester 2, to yield an a ,/3-unsaturated carboxylic ester 4. 

The term Knoevenagel reaction however is used also for analogous reactions of aldehydes and ketones with various types of CH-acidic methylene compounds. The reaction belongs to a class of carbonyl reactions, that are related to the aldol reaction. The mechanism is formulated by analogy to the latter. The initial step is the deprotonation of the CH-acidic methylene compound 2. Organic bases like amines can be used for this purpose a catalytic amount of amine usually suffices. A common procedure, that uses pyridine as base as well as solvent, together with a catalytic amount of piperidine, is called the Doebner modification of the Knoevenagel reaction. 

Virtually any aldehyde or ketone and any CH-acidic methylene compound can be employed in the Knoevenagel reaction however the reactivity may be limited due to steric effects. Some reactions may lead to unexpected products from side-reactions or from consecutive reactions of the initially formed Knoevenagel product. 

Various competitive reactions can reduce the yield of the desired Michael-addition product. An important side-reaction is the 1,2-addition of the enolate to the C=0 double bond (see aldol reaction, Knoevenagel reaction), especially with a ,/3-unsaturated aldehydes, the 1,2-addition product may be formed preferentially, rather than the 1,4-addition product. Generally the 1,2-addition is a kinetically favored and reversible process. At higher temperatures, the thermodynamically favored 1,4-addition products are obtained. 

The aldol-like reaction of an aromatic aldehyde 1 with a carboxylic anhydride 2 is referred to as the Perkin reaction. As with the related Knoevenagel reaction, an o ,/3-unsaturated carboxylic acid is obtained as product the /3-aryl derivatives 3 are also known as cinnamic acids. 

The Knoevenagel reaction is a carbonyl condensation reaction of an ester with an aldehyde or ketone to yield an a,j8-unsaturated product. Show the mechanism of the Knoevenagel reaction of diethyl malonate with benzaldchyde. 

When the reactant is of the form ZCH2Z, aldehydes react much better than ketones and few successful reactions with ketones have been reported. However, it is possible to get good yields of alkene from the condensation of diethyl malonate, CH2(COOEt)2, with ketones, as well as with aldehydes, if the reaction is run with TiCU and pyridine in THF. In reactions with ZCH2Z, the catalyst is most often a secondary amine (piperidine is the most common), though many other catalysts have been used. When the catalyst is pyridine (to which piperidine may or may not be added) the reaction is known as the Doebner modification of the Knoevenagel reaction. Alkoxides are also common catalysts. 

When aliphatic nitro compounds are used instead of aldehydes or ketones, no reduction occurs, and the reaction is essentially a Knoevenagel reaction, though it is usually also called a Tollens reaction ... 

The Knoevenagel reaction between o-hydroxyaryl aldehydes and ketones and substituted acetonitriles affords high yields of 3-substituted coumarins in aqueous alkaline media <96H(43)1257>, whilst 4-hydroxycoumarins have been elaborated to pyrano [3,2-c]benzopyran-5-ones by reaction with aromatic aldehydes and malononitiile <96P148>. The imine (10) resulting from the complex reaction of o-hydroxyacetophenone with malononitrile undergoes a 1,5-tautomeric shift in solution <96JCS(P1)1067>. 

The cz5-aziridine substrate shows, as expected on the basis of this model, predominant formation of the trans-cyclopropane product. The starting materials for this MIRC reaction can readily be obtained from the aziridine esters by reduction to the corresponding aldehyde and a subsequent Knoevenagel reaction with malonate ester (Scheme 25) [34]. 

Besides the domino Michael/SN processes, domino Michael/Knoevenagel reactions have also been used. Thus, Obrecht, Filippone and Santeusanio employed this type of process for the assembly of highly substituted thiophenes [102] and pyrroles [103]. Marinelli and colleagues have reported on the synthesis of various 2,4-disubstituted quinolines [104] and [l,8]naphthyridines [105] by means of a domino Michael addition/imine cyclization. Related di- and tetrahydroquinolines were prepared by a domino Michael addition/aldol condensation described by the Hamada group [106]. A recent example of a domino Michael/aldol condensation process has been reported by Brase and coworkers [107], by which substituted tetrahydroxan-thenes 2-186 were prepared from salicylic aldehydes 2-184 and cycloenones 2-185 (Scheme 2.43). 

So far, only those domino Knoevenagel/hetero-Diels-Alder reactions have been discussed where the cycloaddition takes place at an intramolecular mode however, the reaction can also be performed as a three-component transformation by applying an intermolecular Diels-Alder reaction. In this process again as the first step a Knoevenagel reaction of an aldehyde or a ketone with a 1,3-dicarbonyl compound occurs. However, the second step is now an intermolecular hetero-Diels-Alder reaction of the formed 1 -oxa-1,3 -butadiene with a dienophile in the reaction mixture. The scope of this type of reaction, and especially the possibility of obtaining highly diversified molecules, is even higher than in the case of the two-component transformation. The stereoselectivity of the cycloaddition step is found to be less pronounced, however. 

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