Carbonyl compounds Knoevenagel reaction

Subsequent to Hantzsch s communication for the construction of pyridine derivatives, a number of other groups have reported their efforts towards the synthesis of the pyridine heterocyclic framework. Initially, the protocol was modified by Beyer and later by Knoevenagel to allow preparation of unsymmetrical 1,4-dihydropyridines by condensation of an alkylidene or arylidene P-dicarbonyl compound with a P-amino-a,P-unsaturated carbonyl compound. Following these initial reports, additional modifications were communicated and since these other methods fall under the condensation approach, they will be presented as variations, although each of them has attained the status of named reaction . 

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. 

Iminium ions are intermediates in a group of reactions that form ,( -unsaturated compounds having structures corresponding to those formed by mixed aldol addition followed by dehydration. These reactions are catalyzed by amines or buffer systems containing an amine and an acid and are referred to as Knoevenagel condensations,2U The reactive electrophile is probably the protonated form of the imine, since it is a more reactive electrophile than the corresponding carbonyl compound.212... 

Phosphonothiazolylmethanes 40 react with carbonyl compounds to give the expected alkene products via Knoevenagel or Homer-Wadsworth Emmons reactions. When they are treated with oc-haloketones, pyrrolothiazoles 42 are obtained in a two stage process via the quaternary salt 41 <98PSS251>. 

Knoevenagel reaction org chem The condensation of aldehydes with compounds containing an activated methylene (=Cff2) group. ka ne va.nag al re.ak shan ) Knorr synthesis orgchem Acondensation reaction carried out In either glacial acetic acid or an aqueous alkali in which an a-aminoketone combines with an a-carbonyl compound to form a pyrrole possibly the most versatile pyrrole synthesis. nor, sin-th3-s3s ... 

The Knoevenagel condensation is a cross-aldol condensation of a carbonyl compound with an active methylene compound leading to C-C bond formation (Scheme 7). This reaction has wide application in the synthesis of fine chemicals and is classically catalyzed by bases in solution (146,147). 

The forward synthetic reaction is a base-catalysed condensation reaction between two carbonyl compounds, the aldol condensation leading to -hydroxy-aldehydes or / -hydroxyketones followed by dehydration. This sequence is one of the most important carbon-carbon bond forming reactions, and aldol-type condensation reactions are considered in a number of other sections of the text, for example, the Doebner reaction (Section 5.18.3, p. 805), the Knoevenagel reaction (Section 5.11.6, p. 681), the Perkin reaction (Section 6.12.3, p. 1036) and the Robinson annelation reaction (Section 7.2). 

According to the classical Hantzsch synthesis of pyridine derivatives, an a,(5-unsaturated carbonyl compound is first formed by Knoevenagel condensation of an aldehyde with a P-dicarbonyl compound. The next step is a Michael reaction with another equivalent of the P-dicarbonyl compound (or its enamine) to form a 1,5-diketone, which finally undergoes a cyclocondensation with ammonia to give a 1,4-dihydropyridine with specific symmetry in its substitution pattern. 

A large number of catalytic asymmetric MCR are based on deoxo-bisubstitution reactions of carbonyl compounds such as the Mannich and Strecker reactions in which an oxo-group is displaced by two new cr-bonds, one to a nitrogen atom and one to a carbon atom. Other examples of deoxo-bisubstitutions include tandem processes that involve an initial Knoevenagel condensation followed by either a nucleophilic or a cycloaddition. These processes are characterized by the conversion of a C O-K-bond into two new C-C-cr-bonds and have been termed carba-acetalizations. 

A Knoevenagel reaction is a condensation reaction between an active-methylene compound (or the comparably C,I I-acidic nitromethane) and a carbonyl compound. The product of a Knoevenagel reaction is an alkene that contains two geminal acceptor groups (B in Figure 13.52) or one nitro group (B in Figure 13.53). 

Knoevenagel reaction A condensation reaction in which a methylene unit that has two adjacent -M groups such as carbonyl, ester or nitro groups, reacts in the presence of base with an aldehyde or ketone, that usually does not have an a-hydrogen. Dehydration usually follows to yield the conjugated unsaturated compound. 

II. The formation of afi-unsaturated carbonyl compounds, in which the initial addition reaction is followed by dehydration (Perkin, Knoevenagel, and Claisen-Schmidt condensations). 

The Knoevenagel condensation was also performed with MCM-41-(6112)3-NH-(CH2)2-NH2 catalyst prepared through post-modification methodology/ utilizing (2-aminomethylaminopropyl)trimethoxysilane. Various aldehydes and ketones were reacted with malononitrile and ethyl cyanoacetate (Scheme 3.21, R =R = CN and R CN, R = EtOCO) in all the reactions total conversions were achieved in toluene with exclusive formation of dehydrated products (75-100% yield). Interestingly, both aliphatic and aromatic carbonyl compounds showed identical reactivity in the reaction with ethyl cyanoacetate and the substitution on the aromatic ring did not influence the reactivity. 

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