Enamines Extended

B. The preparation of enamines by heating seeondary amines and ketals was originated by Hoch (118) and has been extended by Bianchetti and eo-workers (119-121). 

If the conjugation of the enamine system is extended, a third site of reaction becomes possible. 

The bulk of enamine studies since Stork s original publication have focused on establishing the breadth and limitations of individual substitution reactions and on extending the list of useful electrophiles. In addition, auxiliary studies have enriched our knowledge about the ambident nature of the vinyl nitrogen system, stereoelectronic factors governing its reactivity, its stability and spectroscopic properties. An increasing number of synthetic applications of these fundamental studies can be expected in future years. 

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 a alkylation of enamines has also been extended to photochemical and thermal reactions of carbon tetrachloride with enamines (292,293). 

Reactions of 3- and 4-piperidone-derived enamines with a dienester gave intermediates which could be dehydrogenated to tetrahydroquinolines and tetrahydroisoquinolines (678). The methyl vinyl ketone annelation of pyrrolines was extended to an erythrinan synthesis (679). Perhydrophenan-threnones were obtained from 1-acetylcyclohexene and pyrrolidinocyclo-hexene (680) or alternatively from Birch reduction and cyclization of a 2-pyridyl ethyl ketone intermediate, which was formed by alkylation of an enamine with a 2-vinylpyridine (681). 

The reactions of enamines with positively activated olefins have been extended to arylations with />-quinones (350,362-369) and quinone sulfoni-mides (365-368,370). Thus a new pathway for the facile formation of benzofurans and indoles became available. 

Enamine acylations have been extended to include the Vilsmeier reaction (409) and thus provide a method for the generation of formyl ketones without the use of strong base. By this method an unsaturated potential trialdehyde could be formed as an intermediate in a pyridine-3-carboxaldehyde synthesis (410). 

Closely related is the reaction of enamines with O-sulfonyl lactams (411-413), which has extended the versatility of Hiinig s carboxylic acid extension sequence to compounds with a terminal amine function. 

At low temperature a 1 1 adduct of thioacetic acid and an enamine could be prepared (709). The previously described reaction of aminomethylene ketones with hydrogen peroxide was extended to bisaminomethylene compounds. However, acylated cyclohexenamines led to cyclopentane-carboxamides (770), Trichloromethyl adducts of enamines and the rearranged amine derivatives were described in a further study (777). 

An unexpected reduction of enamines by secondary amines such as pyrrolidine, piperidine, and particularly hexamethyleneimine was discovered in the formation of the norbomanone enamines and extended to hexamethyleneiminocyclopentene (561,562). 

The editor wishes to extend his thanks to each of the contributors of this book who so willingly gave of their time and talents, and he wishes to extend his personal gratitude to Dr. Nelson J. Leonard for initially stimulating his interest in enamines and for his continuing interest over the years. 

The Simmons-Smith reaction has been used as the basis of a method for the indirect a methylation of a ketone. The ketone (illustrated for cyclohexanone) is first converted to an enol ether, an enamine (16-12) or silyl enol ether (12-22) and cyclopropanation via the Simmons-Smith reaction is followed by hydrolysis to give a methylated ketone. A related procedure using diethylzinc and diiodomethane allows ketones to be chain extended by one carbon. In another variation, phenols can be ortho methylated in one laboratory step, by treatment with Et2Zn and... 

The initial reaction has been extended to the IH of secondary aminoalkynes to give cyclic enamines with an exocyclic C=C bond [304]. 

Cycl[3.2.2]azines may also be obtained by the cycloaddition of a bifunctional three-carbon unit to a 3//-pyrrolizine. Vinamidinium salts have been used for this purpose <1984CB1649>, although the reactions require the use of a strong base (sodium hydride) and extended reaction times. They appear to proceed via a stepwise mechanism, since intermediates (the conjugated enamines 354 and 355) have been isolated in certain cases (Scheme 94). 

The intermolecular ruthenium enyne Alder-ene reaction has been extended to the stereoselective preparation of enamines (Equation (26)).39 The yields obtained for this reaction were high with allylacetamides, -benzamides,... 

Condensation of aryl halides with various active methylene compounds is readily promoted by catalytic action of palladium to give the corresponding arene derivatives containing a functionalized ethyl group [7]. Yamanaka et al. extended this chemistry to haloazoles including oxazoles, thiazoles and imidazoles [8]. Thus, in the presence of Pd(Ph3P)4,2-chlorooxazole was refluxed with phenylsulfonylacetonitrile and NaH to form 4,5-diphenyl-a-phenylsulfonyl-2-oxazoloacetonitrile, which existed predominantly as its enamine tautomer. In a similar fashion, 4-bromooxazole and 5-bromooxazole also were condensed with phenylsulfonylacetonitrile under the same conditions. 

The imine 217, formed from acetophenone and the 1-aminoimidazole, has been transformed into the enamine 218 which is then cyclized to 219 in trifluoroacetic acid (TFA) (Equation 40) <1995SC3271 >. The diaminoimidazole 220 reacts with ynone 221 to form 222 (Equation 41) <1998CHE1189>. Bromochalcones and chalcone dibromides can also be used in place of the ynone. Similar reactions have been used to prepare the dihydro analogues of 222 <1999CHE1207>. The reaction between 1-aminoimidazoles and 1,3-diketones has been extended to prepare bis-heterocyclic compounds, for example, 223 as ligands for transition metals (Equation 42) <2005EJI4382>. 

The high barriers in compounds 31 and 32 may be attributed to the fact that in these compounds the two carbonyl groups are coplanar with the enamine moiety, whereas such a coplanar structure is impossible for the open-chain compounds. Based on this point of view, Kdlle and associates extended the work further and were able to isolate a series of compounds (33,34) in one crystalline atropisomeric form (73). 

Much like the enol systems discussed in Sect. 6.1, enamines are predictably difficult substrates for most iridium asymmetric hydrogenation catalysts. Both substrate and product contain basic functionahties which may act as inhibitors to the catalyst. Extended aromatic enamines such as indoles may be even more difficult substrates for asymmetric hydrogenation with an additional energetic barrier to overcome. Initial reports by Andersson indicated a very difficult reaction indeed (Table 14) [75]. Higher enantioselectivities were later reported by Baeza and Pfaltz (Table 14) [76]. 

Hong and co-workers have described a formal [3-t-3] cycloaddition of a,P-unsaturated aldehydes using L-proline as the catalyst (Scheme 72) [225], Although the precise mechanism of this reaction is unclear a plausible explanation involves both iminium ion and enamine activation of the substrates and was exploited in the asymmetric synthesis of (-)-isopulegol hydrate 180 and (-)-cubebaol 181. This strategy has also been extended to the trimerisation of acrolein in the synthesis of montiporyne F [226],... 

Mannich and Davidsen [31] also reported that most of the aldehydes were first converted to a diamino intermediate which on distillation afforded the enamine. Less successful was the attempt to extend the reaction to ketones. Only with the use of calcium oxide at elevated temperatures were the enamines directly obtained, but in poor yields. Herr and Heyl [32, 33] found that better yields of enamines from ketones can be obtained by the azeotropic removal of water in the presence or absence [32, 33] of acid catalysts [12a, b, 34, 35]... 

The Batcho-Leimgruber indole synthesis is probably the most important and widely used method for the preparation of lH-2,3-unsubstituted indoles. In an attempt to extend the utility of the process to the preparation of 3-substituted indoles, functionalisation of the specific intermediate enamine 1 was explored. Treatment of 1 with ethyl chloroformate in refluxing chloroform in the presence of AT,JV-diethylaniline failed to give the expected ester. Instead, a product was obtained the spectral data for which suggested that it was a dienamine. The same product could be obtained in 52% yield simply by treatment of 1 with half an equivalent of TsOH in toluene at 90°C, and catalytic hydrogenation of this dienamine gave 2 in 58% yield. 

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