Enamine isomerization

Isomerization is a frequent side-reaction of catalytic transformations of olefins, however, it can be a very useful synthetic method, as well. One of the best-known examples is the enantioselective allylamine enamine isomerization catalyzed by [Rh (jR)-or(S)-BINAP (COD)] which is the crucial step in the industrial synthesis of L-menthol by Takasago [42]... 

Reactions proceeding more than once in the transformation of a substrate can be more effective than a single process If the reaction in question is a condensation of an N nucleophile with a carbonyl compound, the combination of the of two such reactions—allows for the synthesis of heterocycles like, the two depicted in Figure 9.27. The synthesis of quinoxaline (B) from glyoxal dihydrate (A) and orfho-phenylene diamine consists of two imine formations. Somewhat more complicated is the synthesis of dimethylpyrrole D from acetonyl acetone (C) and ammonia. After the formation of the first imine, an imine enamine isomerization occurs. A condensation followed by another imine — enamine isomerization leads to the product. 

The three-step protocol (photo-oxygenation in the presence of DBU/ imine to enamine isomerization/hydrogenation with optically active Rh(I)/ DIPAMP combination as catalyst) leads in high yields and excellent ee to... 

Papaverine.—The biosynthesis of the simple benzylisoquinoline papaverine (89) is known to proceed via nor-reticuline (48) and tetrahydropapaverine (88).71 Dehydrogenation of the latter affords papaverine, and examination of the stereochemistry of the processes involved has led to the conclusion72 that loss of the proton at C-3 [in nor-reticuline (48)] is stereospecific (loss of the pro-S hydrogen atom) but removal of the C-4 proton is essentially non-stereospecific. These observations are perhaps best explained if enzyme-catalysed oxidation of (88) occurs to give (90), subsequent non-stereospecific imine-enamine isomerization occurring without enzyme participation to give (91). A further amine to imine oxidation then occurs to give papaverine (89).72... 

Asymmetric allylamine-to-enamine isomerizations can be readily applied to bifunctional C5-isoprenoid substrates, which contain an allylic dialkylamino function at the tail end and an allylic O-function at the head end. 

Rivire and Lattes used LiNH2 and NaNHj in liquid ammonia at — 70°C, in hexamethylphosphortriamide at room temperature or t-BuOK/HMPA at room temperature for allylamine enamine isomerizations. An anion formed by deprotonation of the allylamine at C was considered to be the intermediate species in the isomerization. Intramolecular transfer of hydrogen in the transition state of the isomerization was suggested to explain both the kinetic formation of the Z-enamine and the absence of exchange with deuteriated base during the isomerization. Quantum chemical calculations showed that the Z-carbanion (61) is actually more stable than the -carbanion (62). 

I- 3] product 180 (equation 37). The silyl group is protodesilylated under the reaction conditions. For cyclic enamines, isomerization of 178 to 181 by a 1,5-silyl shift intervenes, followed by Mannich reaction giving a [4 -t- 2] product 182. 

We propose the biosynthetic pathway of the carbon framework of matrine as shown in Fig. 4. This scheme also indicates the pathway for the formation of sparteine and lupanine. The former part of this scheme was proposed by Wink et al. [63], with minor modification by Leete [64], from the in vitro experiments using isolated chloroplasts of leaves of Lupinus. They postulated the presence of 17-oxosparteine as the first key intermediate for the formation of lupanine and sparteine [63]. However, this hypothesis involving 17-oxosparteine synthase was not confirmed by the tracer experiments using and independently conducted by the groups of Spenser [65, 66] and Robins [67]. They, in turn, hypothesized the pathway involving the diiminium cation (73) as the tetracyclic intermediate [68, 69]. The postulation of the presence of this reactive intermediate is consistent with the results of isotope incorporation into lupanine and sparteine. The biosynthetic scheme of matrine can be also drawn by involving the electronically equivalent diiminium cation (76) preceded by additional 1,3-hydride shift or imine-enamine isomerization (74 75). All these reactions take... 

FIGURE 14.6 Strategy for the use of the sequential intramolecular azide-aUcene cycloaddi-tion/nitrogen extrusion/unine-enamine isomerization/nucleophilic addition. 

A synthesis of optically active citroneUal uses myrcene (7), which is produced from P-piaene. Reaction of diethylamine with myrcene gives A/,A/-diethylgeranyl- and nerylamines. Treatment of the aHyUc amines with a homogeneous chiral rhodium catalyst causes isomerization and also induces asymmetry to give the chiral enamines, which can be readily hydrolyzed to (+)-citroneUal (151). 

The reaction of vinylogous amides, or ketoaldehydes, with hydroxylamine produced 4,5,6,7-tetrahydro-l,2-benzisoxazole. A side product is the 2,1-benzisoxazole (Scheme 173) (67AHC(8)277). The ring system can also be prepared by the reaction of cyclohexanone enamines with nitrile oxides (Scheme 173) (78S43, 74KGS901). Base treatment produced ring fission products and photolysis resulted in isomerization to benzoxazoles (76JOC13). 

Allylamines have been used as nitrogen protective groups. They can be removed by isomerization to the enamine (t-BuOK, DMSO) or by rhodium-catalyzed isomerization. ... 

An interesting preparation of substituted o-aminophenols has been developed by Birkofer and Daum (30). 2-Acylfurans (8) plus an aliphatic secondary amine presumably condense to give the eorresponding enamine (9) (not isolated), which undergoes thermal isomerization to the o-amino-phenol (10). 

The general rule has been formulated (P) that the less substituted enamine is formed from unsymmetrical ketones such as the 2-alkylcyclohexanones. In enamine 21 the R, group and the N-alkyl groups would interfere with one another if overlap is to be maintained between the nitrogen unshared electrons and the double bond. There would be less repulsion if the isomeric enamine (22) were formed. 2-Phenylcyclohexanone and pyrrolidine with p-toluenesulfonic acid as catalyst in refluxing benzene gave enamine... 

The piperidine, pyrrolidine, and morpholine enamines of cyclohexanone substituted in the 3-position by methyl, phenyl, and l-butyl have been prepared (49). The complexity of the NMR spectra in the ethylenic hydrogen region indicated a mixture of isomeric enamines. Estimation of the per cent of each isomer by examination of the NMR spectra was not possible, nor were the isomeric enamines separable by vapor-phase chromatography. 

Enamines of several methyl ketones have been prepared and their isomer content estimated by NMR spectroscopy (13,39,43). The reaction of Ti[N(CH3)2l4 as the amine source and 3-methyl-2-butanone gave only 26 (Ri = Rj = CH3), which could be isomerized by prolonged heating to a 1 1 mixture ofthatenamine and enamine 27 (R, = Rj = CH3)(39). The reaction of morpholine and 3-methyl-2-butanone in benzene with a trace of acetic... 

The addition of secondary amines to 1-cyanoallenes (161) results in the formation of enamines in 80-90% yield (124). Addition can occur at the 1,2 or 2,3 double bonds so that a mixture of isomeric enamines (162 and 163) is formed. The ratio of products is influenced by the alkyl substituents on the cyanoallenes and the structure of the secondary amine. 

Treatment of allylamines with potassium amide on alumina causes their isomerization to enamines in good yields (124b). When allylamines are heated to about 55° the same type of isomerization takes place (I24c). 

The base-catalyzed isomerization of N,N-dialkylallylamines (179) to a mixture of enamines consisting primarily of the cis isomer (180) has been reported 128). The assignments were based upon the magnitude of the... 

The previous sections have dealt with stable C=N-I- functionality in aromatic rings as simple salts. Another class of iminium salt reactions can be found where the iminium salt is only an intermediate. The purpose of this section is to point out these reactions even though they do not show any striking differences in their reactivity from stable iminium salts. Such intermediates arise from a-chloroamines (133-135), isomerization of oxazolidines (136), reduction of a-aminoketones by the Clemmensen method (137-139), reductive alkylation by the Leuckart-Wallach (140-141) or Clarke-Eschweiler reaction (142), mercuric acetate oxidation of amines (46,93), and in reactions such as ketene with enamines (143). 

A substituted a,/3-unsaturated aldehyde, cinnamaldehyde, has been observed to undergo the same type of two-step 1,3-cycloaddition reaction with a cyclohexanone enamine as acrolein does, forming in this case a stereo-isomeric mixture of substituted bicycloaminoketones in excellent yield (29a,31a,31b). 

In a similar manner diethyl maleate (actually diethyl fumarate since the basic enamine catalyzes the maleate s isomerization upon contact) forms unstable 1,2 cycloadducts with enamines with hydrogens at temperatures below 30°C (37). At higher temperatures simple alkylated products are formed (41). Enamines with no )3 hydrogens form very stable 1,2 cycloadducts with diethyl maleate (36,37,41). The two adjacent carboethoxy groups of the cyclobutane adduct have been shown to be Irons to one another (36,37). 

If the a position of an enamine is carbon substituted, providing the possibility of an isomeric enamine, and if the amine group and other substituent groups are sufficiently removed from the sites of electrophilic attack as to not cause any steric interference, then simple alkylation of an enamine by an acrylate ester can be followed with a second electrophilic... 

Azides can use enamines as dipolarophiles for ],3 cycloadditions to form triazolines. These azides can be formate ester azides (186), phenyl azides (187-195), arylsulfony] azides (191-193,196), or benzoylazides (197,198). For example, the reaction between phenyl azide (138) and the piperidine enamine of propionaldehyde (139) gives 1 -phenyl-4-methy l-5-( 1 -piperidino)-4,5-dihydro-l,2,3-triazole (140), exclusively, in a 53% yield (190). None of the isomeric l-phenyl-5-methyl product was formed. This indicates that the... 

Cyclic enamines with an isomeric position of the double bond have been obtained by the addition of Grignard reagents to five- (78-81), six- (82-86), seven- (87-90), and thirteen- (89-91) membered lactams, whereas other medium-sized (92,93) lactams furnished amino ketones. The reaction has been extended to substituted lactams (94-98), and iminoethers (99,100). 

The addition of secondary amines to acetylenes is most applicable to the synthesis of conjugated acyclic enamines (50,171,172). Particularly the addition to acetylenic esters and sulfones has been investigated (173-177) and it appears that an initial trans addition is followed by isomerization to more stable products where the amine and functional group are in a trans orientation (178). Enamines have also been obtained by addition of secondary amines to allenes (179). 

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