Enamine Derivatives

Enamines derived from ketones are allylated[79]. The intramolecular asymmetric allylation (chirality transfer) of cyclohexanone via its 5-proline ally ester enamine 120 proceeds to give o-allylcyclohexanone (121) with 98% ee[80,8l]. Low ee was observed in intermolecular allylation. Similarly, the asymmetric allylation of imines and hydrazones of aldehydes and ketones has been carried out[82]. 

An interesting and useful property of enamines of 2-alkylcyclohexanones is the fact that there is a substantial preference for the less substituted isomer to be formed. This tendency is especially pronounced for enamines derived from cyclic secondaiy amines such as pyrrolidine. This preference can be traced to a strain effect called A or allylic strain (see Section 3.3). In order to accommodate conjugation between the nitrogen lone pair and the carbon-carbon double bond, the nitrogen substituent must be coplanar with the double bond. This creates a steric repulsion when the enamine bears a p substituent and leads to a... 

These steric factors are also indicated by the relative basicity of enamines derived from five-, six-, and seven-membered ketones. The five- and seven-membered enamines are considerably stronger bases, indicating better conjugation between the amine lone pair and the double bond. The reduced basicity of the cyclohexanone enamines is related to the preference for exo and endo double bonds in six-membered rings (see Section 3.10). 

The pAT values of the conjugate acids of several enamines derived from 2-methyl-propanal have been reported. Rationalize the observed variation with the structure of the amino constituent. 

Schaeffer and Jain (19) have also reported the synthesis of optically active dehydrocycloheximide (24) by using optically active piperidine enamine derived from (+)-/ra 5-2,4-dimethylcyclohexanone. 

Recent work (5) using kinetic methods has shown that the enamines derived from isobutyraldehyde are indeed less basic than the corresponding saturated tertiary amines. 

Because of self-condensation under the conditions of the alkylation reaction, enamines derived from acetaldehyde or monosubstituted acetaldehydes cannot usually be alkylated 28) except when there is a bulky secondary amine used to produce the enamine 32a). In these cases C alkylation takes place in good yield. 

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

Enamines prepared from the more basic amines are alkylated more easily and in higher yield, but yields are also affected by the ease of formation of an exocyclic double bond in the transition state (32). Thus the enamines derived... 

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). 

The enamines derived from cyclic ketones give the normal alkylated products, although there is some evidence that unstable cycloadducts are initially formed (55b). Thus the enamine (28) derived from cyclohexanone and pyrrolidine on reaction with acrylonitrile, acrylate esters, or phenyl vinyl sulfone gave the 2-alkylated cyclohexanones (63) on hydrolysis of the intermediates (31,32,55,56). These additions are sensitive to the polarity of the solvent. Thus (28) in benzene or dioxane gave an 80% yield of the... 

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). 

The reaction of enamines derived from cyclohexanone with dichlorocarbene to give the 1 1 adducts is now well established (137-139). The morpholine enamine (113) reacted with dichlorocarbene at —10 to —20° in tetrahydrofuran to give the stable crystalline adduct (201). Thermal decomposition followed by an aqueous work-up gave an a,)3-unsaturated ketone identified as 2-chloromethylene-cyclohexan-l-one (202) (139). 

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). 

Dihydropyrans have been produced by the 1,3 cycloaddition of methyl vinyl ketone (77) or acrolein (29-J7) with enamines (see Section II.A.2). S-Lactones have been formed as a side product in the reaction of dimethyl ketene with enamines (77), and as the primary products in the reaction of excess ketene with enamines derived from ketones (75) (see Section II.A.4). 

The photocyclization of N-aryl enamines derived from cyclic or acyclic ketones proceeds under mild conditions to produce 2,3-dihydroindole derivatives (178b). The stereochemistry of the products is predominantly trans, which follows from a photochemical electrocyclic process which should take place in a conrotatory manner (178c,I78d). However, the presence of some cis products is not as easily explained. 

Enamines derived from 1-azabicycloalkanes, readily accessible by mercuric acetate oxidation of saturated bases (112), have been extensively studied recently (113-115). Since an immonium salt is formed during dehydrogenation, the composition of the liberated enamine mixture shows the relative stability of the various possible isomers. The study of infrared and NMR spectra has shown that the position of the enamine double bond is determined by factors similar to those determining the relative stability of simple olefins. 

The simplest examples of this type of compound are enamines derived from the quinuclidine skeleton (67). The formulation of enamines of qflmuclidine in a inesomeric form would violate Bredt s rule. Actually, the ultraviolet spectrum of 2,3-benzoquinuclidine shows that there exists no interaction of aromatic ring tt electrons and the nitrogen-free electron pair (160,169). The overlap of the olefinic tt orbital and the lone pair orbital on nitrogen is precluded. 

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. 

Enamine derivatives have also found use in the alkylation of /3-keto-esters. Greater selectivity for monoalkylation products and consequently greatly improved yields have been reported (284-287). 

It is interesting to see that the addition of methyl acrylate to the pyrrolidine enamine derivative of 2-methylcyelohexanone in benzene gave equal amounts of 2-methyl-2-carbomethoxyethyl and 2-methyl-6-earbomethoxy-ethylcyclohexanone even though the less substituted double-bond isomer predominates in the starting enamine (199,200,237). In contrast, the methylation of the same enamine mixture led only to 2,6-dimethyleyclo-... 

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). 

A two-carbon ring expansion of cyclic ketones was achieved by the addition of acetylenic esters and diesters to the enamine derivatives of the ketones, and reported almost simultaneously from several laboratories (337-343). The intermediate bicyclic adduct could be isolated in some cases. 

Dicarbomethoxyacetylene has also been added to the pyrrolidine enamine derivative of acetylacetone, demonstrating a new synthesis of phthalic esters (345). A 3-acylpyridine synthesis was achieved by the addition of an acetylenic aldehyde to the vinylogous amide derived from ammonia and dihydroresorcinol (346). 

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). 

In the acylation of enamines derived from 3-substituted cyclohexanones, 6-acylated products were favored over 2-acylated products (398), thus revealing another selective enamine reaction sequence. The use of oxalyl bromide for the acylation of enamines has also been described (399). 

While most acylation and benzoylation studies have involved enamines derived from cyclic ketones, extensions to aldehyde derived enamines have also been successful (400). 

The acylation of enamines derived from cyclic ketones, which can lead to the acyl ketone or ring expansion (692-694), was studied by NMR and mass spectroscopic analysis of the products (695,696). In a comparative study of the rates of diphenylketene addition to olefins, a pronounced activation was observed in enamines (697). Enamine N- and C-acylation products were obtained from reactions of Schiff s bases (698), vinylogous urethanes (699), cyanamides (699), amides (670,700), and 2-benzylidene-3-methylbenzothiazoline (672) with acid chlorides, anhydrides, and dithio-esters (699). 

The selective bromination of a ketone in the presence of another susceptible functional group was achieved in a diterpene synthesis 240). A competing bromination of an anisole ring could be avoided here through the use of a pyrrolidine enamine derivative for activation of the methylene group adjacent to the carbonyl function. 

The formation of enamines from carbonyl compounds and secondary amines usually entails as only questionable structural feature, the possible isomeric position of double bonds in the product. Molecular rearrangements have not presented synthetic limitations. A notable exception is the generation of o-aminophenols on distillation of enamines derived from 2-acylfurans 620,621). 

The use of hydrazone or enamine derivatives of ketones or aldehydes offers the advantage of stcreocontrol via chelated azaenolates. Extremely useful synthetic methodology, with consistently high anti selectivity, has been developed using azaenolates based on (S)- or (R)-l-amino-2-(methoxymethyl)pyrrolidine (SAMP or RAMP)51 58 (Enders method, see Section 1.5.2.4.2.2.3.). An example which illustrates the efficiency of this type of Michael addition is the addition of the lithium azaenolate of (5 )-l-amino-2-(methoxymethyl)pyrrolidine (SAMP) hydrazone of propanal (R = II) to methyl (E )-2-butenoate to give the nub-isomer (an 1 adduct) in 80% yield with a diastereomeric ratio > 98 2,... 

The Michael additions of chiral cycloalkanone imines or enamines, derived from (FV l-l-phcnyl-ethanamine or (5)-2-(methoxymethyl)pyrrolidine, are highly diastereofacially selective reactions providing excellent routes to 2-substituted cycloalkanones. This is illustrated by the addition of the enamine of (S)-2-(methoxymethyl)pyrrolidine and cyclohexanone to 2-(aryl-methylene)-l,3-propanedioates to give, after hydrolysis, the (2 5,a.S )-oxodicstcrs in 35-76% yield with d.r. (2 S,aS)/(2 S,a/ ) 94 6- > 97 3 and 80-95% ee214. 

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). 

Primary and secondary halides do not perform well, mostly because N-alkylation becomes important, particularly with enamines derived from aldehydes. An alternative method, which gives good yields of alkylation with primary and secondary halides, is alkylation of enamine salts, which are prepared by treating an imine with ethylmagnesium bromide in THF ... 

Ketones and carboxylic esters can be a hydroxylated by treatment of their enolate forms (prepared by adding the ketone or ester to LDA) with a molybdenum peroxide reagent (MoOs-pyridine-HMPA) in THF-hexane at -70°C. The enolate forms of amides and estersand the enamine derivatives of ketones can similarly be converted to their a hydroxy derivatives by reaction with molecular oxygen. The M0O5 method can also be applied to certain nitriles. Ketones have also been Qc hydroxylated by treating the corresponding silyl enol ethers with /n-chloroperoxy-... 

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