Aldehydes, addition derivatives condensation reactions

A condensation reaction leads to a product with a new C—C bond. Most often the new bond results from a nucleophilic addition of a reasonably stable carbanion-enolate to the C=0 group (acceptor) of an aldehyde less frequently the 0=0 group belongs to a ketone or acid derivative. Another acceptor is the C=N group of a nitrile. 

This topological rule readily explained the reaction product 211 (>90% stereoselectivity) of open-chain nitroolefins 209 with open-chain enamines 210. Seebach and Golinski have further pointed out that several condensation reactions can also be rationalized by using this approach (a) cyclopropane formation from olefin and carbene, (b) Wittig reaction with aldehydes yielding cis olefins, (c) trans-dialkyl oxirane from alkylidene triphenylarsane and aldehydes, (d) ketenes and cyclopentadiene 2+2-addition, le) (E)-silyl-nitronate and aldehydes, (f) syn and anti-Li and B-enolates of ketones, esters, amides and aldehydes, (g) Z-allylboranes and aldehydes, (h) E-alkyl-borane or E-allylchromium derivatives and aldehydes, (i) enamine from cyclohexanone and cinnamic aldehyde, (j) E-enamines and E-nitroolefins and finally, (k) enamines from cycloalkanones and styryl sulfone. 

Aldehydes can arise by Reactions C, D, and E, and they can then react with each other by the aldol condensation. Amines (and particularly their salts), including peptones and egg albumin, are effective catalysts. Additional carbonyl compounds which can participate in the condensation may be derived by the oxidation of lipids. 

There are a number of variations of the condensation reaction of acid derivatives. The reaction between a cyclic ketone having a pendant alkynyl ester unit and tetra-butylammonium fluoride leads to cyclization to a bicyclic alcohol with an exocyclic allene moiety. A chain-extension reaction culminates in acyl addition of an ester enolate. The reaction of a p-keto ester, such as methyl 3-oxobutanote and EtZnCH2k leads to chain extension via a carbenoid-like insertion reaction (p. 803), which reacts with an aldehyde in a second step to give a methyl 3-oxopentanoate derivative with a —CH(OH)R group at C-2 relative to the ester carbonyl. ... 

The addition of dialkylaminostannanes to aldehydes and ketones often gives a mixture of tin-free products derived from addition and elimination reactions of the monomeric carbonyl compound and of its products of base-catalysed aldol condensation. With appropriate substituents, however, reasonable yields of the enamines can be isolated, for example 38... 

A variety of heterocyclic compounds have been derived from the condensation of aldehydes with a-amino acids. Imines 1 (Fig. 3) are often used as intermediates in organic synthesis and are the starting point for chemical reactions such as cycloadditions, condensation reactions, and nucleophilic additions. The formation of imines via condensation of amines with aldehydes was first adopted for the reductive alkylation of resin-bound amino acids [29-31]. Imines have now been used as synthetic intermediates in the generation of a range of heterocyclic combinatorial libraries. 

It does not form, however, an addition-product with ammonia similar to that derived from aldehyde, but complex condensation products. When reduced by nascent hydrogen generated by the action of sodium amalgam on water, addition takes place as indicated above, and isopropyl alcohol is formed, but at the same time a dihydroxy alcohol, which contains six carbon atoms, is produced in appreciable quantities. This substance, called pinacol, is the first member of a series of such alcohols which are formed by the reduction of ketones. The equation for the reaction in the case of acetone is,... 

B.iv. Nitrile Enolates. Nitrile enolates are formed by reaction of a nitrile with LDA or another suitable base. Both alkylation 30 and condensation reactions with aldehydes 3 or ketones are known. 32 in addition to alkyl halides and carbonyl derivatives, condensation can occur with another nitrile. The base-catalyzed condensation of two nitriles to give a cyano-ketone, via an intermediate cyano enolate, is known as the Thorpe reaction. 33.109e Reaction of butanenitrile with sodium ethoxide gave a nitrile enolate, which reacted with a second molecule of butanenitrile at the electrophilic cyano carbon to give 206. Hydrolysis gave an intermediate imine-nitrile (207), which is in equilibrium with the enamine form (208, sec. 9.6.A). Hydrolysis led to the final product of the Thorpe reaction, an a-cyano ketone, 209. 33 Mixed condensations are possible when LDA and kinetic conditions are used to generate the a-lithionitrile (a mixed Thorpe reaction). When pentanenitrile was treated with LDA and condensed with benzonitrile, 2-cyano-l-phenyl-1-pentanone was the isolated product after acid hydrolysis. Nitrile enolates can also be alkylated with a variety of alkyl halides. 34... 

B.vii. Acid Dianions. All of the named reactions discussed in Section 9.4 constitute relatively minor variations of the fundamental condensation reaction of aldehydes, ketones, or acid derivatives with another aldehyde, ketone, or acid derivative. The ability to produce kinetic enolates from acid derivatives has made possible another useful modification of the enolate reaction. Carboxylic acids have an acidic proton that is removed by 1 equivalent of base to first give a carboxylate (see 226). Addition of a second equivalent of a powerful base such as a dialkylamide leads to the dianion (227). Subsequent reaction with an electrophilic species, in this case 1-bromobutane, occurred first at the more nucleophilic a-carbon to give hexanoic acid. 2 The carboxylate is usually generated with n-butyllithium and the enolate with LDA, although 2 equivalents of LDA can be used. As discussed in Chapter 8, treatment of a carboxylic acid with an excess of an organo-... 

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