Asymmetric hydrogenation amides

In recent years, the catalytic asymmetric hydrogenation of a-acylamino acrylic or cinnamic acid derivatives has been widely investigated as a method for preparing chiral a-amino acids, and considerable efforts have been devoted for developing new chiral ligands and complexes to this end. In this context, simple chiral phosphinous amides as well as chiral bis(aminophosphanes) have found notorious applications as ligands in Rh(I) complexes, which have been used in the asymmetric hydrogenation of a-acylamino acrylic acid derivatives (Scheme 43). 

Asymmetric hydrogenation of a cyclic enamide (Approach B) had very sparse literature precedents [7]. It should also be noted that preparation of these cyclic imines and enamides is not straightforward. The best method for the synthesis of cyclic imines involves C-acylation of the inexpensive N-vinylpyrrolidin-2-one followed by a relatively harsh treatment with refluxing 6M aqueous HC1, which accomplishes deprotection of the vinyl group, hydrolysis of the amide, and decarboxylation (Scheme 8.6) [8]. 

With all other pieces of the synthesis in place our attention now focused on the final piece in the jigsaw-the asymmetric hydrogenation of the amide enamide 42. Screening of hydrogenation conditions rapidly led to identification of a number of conditions which allowed the desired hydrogenation to proceed at low catalyst loadings and in non-chlorinated solvents (Table 9.9). 

Table 10 Asymmetric hydrogenation of some a-keto esters or amides...

Gridnev et al. showed in their study of the asymmetric hydrogenation of en-amides by Rh-catalysts another useful application of coupling constant patterns. By selectively labeling certain atoms, for example with 13C or 2D, additional couplings appear (as compared to the non-labeled product) and this will provide information about the exact structure [22]. 

Reduction of amides without hydride reagents Asymmetric hydrogenation of un functionalized olefins/enamines/imines... 

Iridium-Catalyzed Asymmetric Hydrogenation of Olefins with Chiral N,P and C,N Ligands 55 Table 4 Asymmetric hydrogenation of a-substltuted a,(3-unsaturated amides with ligand 24... 

A resolution of racemic CHIRAPHOS ligand has been achieved using a chiral iridium amide complex (Scheme 8.3). The chiral iridium complex (- -)-l reacts selectively with (S.S -CHIRAPHOS to form the inactive iridium complex 2. The remaining (R,R)-CHIRAPHOS affords the catalytically active chiral rhodium complex 3. The system catalyzes asymmetric hydrogenation to give the (5)-product with 87% ee. The opposite enantiomer (—)-l gives the (R)-product with 89.5% ee, which is almost the same level of enantioselectivity obtained by using optically pure (5,5)-CHlRAPHOS. 

Rhodium-catalyzed asymmetric hydrogenation of dehydroamino acids and en-amides is an efficient method for the preparation of optically active amino acids and... 

I 5 Synthesis of Sitagliptin, the Active Ingredient in Januvia " and Janumet" Table 5.2 Asymmetric hydrogenation of unprotected enamine-amide 27. 

Asymmetric hydrogenation of a-keto esters and amides has been extensively studied with a variety of chiral Rh and Ru catalysts [3,4,46]. A limited number of catalysts have achieved high enantioselectivity. 

Rhodium-BisP and -MiniPHOS catalysts are capable of high enantioselective reductions of dehydroamino acids in 96-99.9% ee.109 A variety of aryl enamides give optically active amides with 96-99% ee with the exception of ort/jo-substituted substrates.111 Despite the high enantio-selectivity, the rate of reaction in this transformation is slow. Rhodium-BisP and -MiniPHOS catalysts perform excellently in the asymmetric reduction of ( >P-(acylamino)acrylates to the corresponding protected-P-amino esters in 95-99% ee.112 Within the family of BisP and MiniPHOS, the ligands that contain t-Bu groups were found to be the most effective in a variety of asymmetric hydrogenations. 

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