Aldehydes enamines from

Enamines ° form four-membered rings with Michael-type aikenesand ketenes.In both cases, only enamines from aldehydes give stable four-... 

The formation of covalent substrate-catalyst adducts might occur, e.g., by single-step Lewis-acid-Lewis-base interaction or by multi-step reactions such as the formation of enamines from aldehydes and secondary amines. The catalysis of aldol reactions by formation of the donor enamine is a striking example of common mechanisms in enzymatic catalysis and organocatalysis - in class-I aldolases lysine provides the catalytically active amine group whereas typical organocatalysts for this purpose are secondary amines, the most simple being proline (Scheme 2.2). 

Enamines from aldehydes and acyclic ketones can form E-( 1) and Z-(2) stereoisomers. The stereoisomer distribution of several of these enamines are shown in Table 1. The principal factor responsible for this distribution is a A(1,3) strain. 

The reaction of a primary amine with a ketone to form an imine is generally quite straightforward, with the techniques typically used for water removal in the formation of enamines (see Section 4.1.2.1) also applicable here. As with the formation of enamines from aldehydes, preparation of the corresponding aldehyde imines can be difficult, especially with relatively unhindered aldehydes where formation of the double amine addition product can occur. However, these aminals often undergo loss of one amine unit thermally (typically during distillation) to generate the imine (Scheme 16). ... 

Pyrrolidine is the secondary amine used most often for making enamines from aldehydes and... 

One of the following is often used to prepare enamines from aldehydes and ketones. The others do not yield enamines. Identify the enamine-forming compound. 

Enamines from the Condensation of Aldehydes and Ketones with Secondary Amines. ... 

The most versatile method for preparing enamines involves the condensation of aldehydes and ketones with secondary amines [Eq. (1)]. Mannich and Davidsen (/) discovered that the reaction of secondary amines with aldehydes in the presence of potassium carbonate and at temperatures near 0° gave enamines, while calcium oxide and elevated temperatures were required to cause a reaction between ketones and secondary amines, although usually in poor yield. The introduction by Herr and Heyl 2-4) of the removal of the water produced in the condensation by azeotropic distillation with benzene made possible the facile preparation of enamines from ketones and disubstituted aldehydes. 

The overall reaction pathway usually presented (/,9,/9,36)for the preparation of an enamine from an aldehyde bearing an a-hydrogen and a secondary amine is given in Eqs. (2) and (3). Intermediate 16, which can be isolated in... 

That an aminal is a necessary intermediate was first questioned by Herr and Heyl (2). They found that by using a slight excess of amine the yield of the enamine from two of the steroidal aldehydes studied was 84%. Also, the -fluorocnamines discussed earlier are formed in 60-90% yield from equimolar amounts of the 8-fluoroaldehyde and secondary cyclic amine (27). However, neither of these studies was specifically designed to show whether or not aminals were intermediates. 

For purposes of characterization of enamines the perchlorate salts are preferred, as they crystallize well, and the perchlorate anion has no tendency to add to the iminium cation. Other salts, including hexachlorostannates (13), hexachloroantimonates (13), chlorides, bromides, tetraphenylborates, and nitrates, have also been used. Recently a method for the preparation of iminium salts directly from aldehydes or ketones and the amine perchlorate has been reported (16). 

Enamines derived from aldehydes disubstituted on the jS carbon such as those derived from isobutyraldehyde (16) are alkylated on nitrogen by alkyl... 

In the case of enamines derived from aldehydes a cycloaddition to give a cyclobutane occurs (48-50). Thus the enamine (16) reacted with methyl acrylate in acetonitrile to give a 91 % yield of methyl 2-dimethylamino-3,3-dimethylcyclobutane carboxylate (56). Similarly, treatment of (16) with diethylmaleate at 170° gave a 70% yield of diethyl 4-dimethylamino-3,3-dimethyl-l,2-cyclobutanedicarboxylate (57), and 16 and acrylonitrile gave a 65% yield of 2-dimethylamino-3,3-dimethylcyclobutanecarbonitrile (58). 

The simple addition of acrolein to enamines derived from aldehydes to give substituted glutardialdehydes has also been observed (54). 

Nonactivated terminal acetylenes have been added to enamines derived from aldehydes. A long reaction time or catalysis by copper(I) chloride is necessary. Thus the enamine (16) formed the adduct (72) on heating with phenylacetylene (64). 

Alkyl sulfonyl chlorides, having an a-hydrogen atom, react with enamines derived from aldehydes and cyclic ketones in the presence of triethylamine to give cyclic sulfones. Thus the enamine (22) gave the four-membered cyclic aminosulfone (143) on reaction with methanesulfonyl chloride (95). 

H. Reaction with Formic and Trichloroacetic Acids Enamines derived from aldehydes have been treated with formic acid under the conditions of the Leuckart-Wallach reaction 141) to give saturated tertiary amines 142). The enamine (98) reacts vigorously with formic acid at room temperature to give N-isobutyl morpholine (204). 

Enamines derived from aldehydes can usually be obtained by the reaction of 2 equivalents of a secondary amine with the carbonyl compound, in the presence of anhydrous potassium carbonate, followed by pyrolytic distillation of the aminal with elimination of one of the amine groups (10,15, 30-36). Ketones are directly converted to enamines under the conditions of aminal formation. The azeotropic removal of water with excess aldehyde has also been described (32,37). 

A fundamental problem in the alkylation of enamines, which is inherent in the bidentate system, is the competition between the desired carbon alkylation and attack at the nitrogen. With unactivated alkyl halides (3,267), this becomes especially serious with the enamines derived fromcycloheptan-one, cyclooctanone, cyclononanone, and enamines derived from aldehydes. Increasing amounts of carbon alkylation are found with the more reactive allyl and benzyl halides (268-273). However, with allyl halides one also observes increasing amounts of dialkylation of enamines. 

Similarly, methyl vinyl ketone has been added to enamines derived from aldehydes (3,321,324-327) and ketones (3,328), providing a useful extension of the Robinson annelation reaetion. Condensations of enamines with other a, 3-unsaturated ketones can give a variety of diketones (329). 

The reactions of enamines with aldehydes (329,350) are noteworthy in that they provide a route to the monobenzylidene derivatives of five- to seven-membered eyclic ketones as well as a method for the formation of other a, 9-unsaturated carbonyl compounds, in fair to good yields. The condensation of benzaldehyde with enamines is also involved in the formation of 3,5-dibenzylpyridine from piperidine and benzaldehyde (191-193). 

The reactions of dichlorocarbene with morpholine and piperidine enamines derived from cyclopentanone and cyclohexanone have been reported to lead to ring expanded and a-chloromethylene ketone products (355,356). Similarly a-chloro-a, -unsaturated aldehydes were obtained from aldehyde derived enamines (357). Synthesis of aminocyclopropanes (353,359) could be realized by the addition of diphenyldiazomethane (360) and the methylene iodide-zinc reagent to enamines (367). 

The condensation of sulfonyl chlorides with enamines (452,453) derived from aldehydes and ketones has led to four-membered-ring sulfones, presumably through such intermediates (454-464). Open sulfonation products have also been obtained, particularly from ketone-derived enamines and from a-disubstituted sulfonyl chlorides. 

Addition of ( )-enamines 3, derived from aldehydes and ketones, to various benzylideneimini-um salts 2 has been investigated. The reaction exclusively gives the Mannich bases anti-4 in good to excellent yield (72-94%). Therefore, this method provides an efficient and highly stereoselective route to /i-amino ketones and aldehydes1415. 

Diastereoselective and enantioselective [3C+2S] carbocyclisations have been recently developed by Barluenga et al. by the reaction of tungsten alkenylcarbene complexes and enamines derived from chiral amines. Interestingly, the regio-chemistry of the final products is different for enamines derived from aldehydes and those derived from ketones. The use of chiral non-racemic enamines allows the asymmetric synthesis of substituted cyclopentenone derivatives [77] (Scheme 30). 

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