A-Amino acids asymmetric hydrogenation

Unsaturated a - Amino-acids Asymmetric Hydrogenation Protection and Deprotection... 

Synthesis of Unsaturated a-Amino-acids Asymmetric Hydrogenation of Amino-acids Protection and Deprotection of Amino-acids Peptide Synthesis... 

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). 

The pharmaceutical industry has been giving increased attention to homogeneous asymmetric hydrogenation for the synthesis of chiral molecules due to significant improvements in this technology (1). We recendy synthesized a chiral a-amino acid intermediate using Et-DuPhos-Rh catalyst, obtaining enantiomeric pmities (EP) of... 

The use of rhodium catalysts for the synthesis of a-amino acids by asymmetric hydrogenation of V-acyl dehydro amino acids, frequently in combination with the use of a biocatalyst to upgrade the enantioselectivity and cleave the acyl group which acts as a secondary binding site for the catalyst, has been well-documented. While DuPhos and BPE derived catalysts are suitable for a broad array of dehydroamino acid substrates, a particular challenge posed by a hydrogenation approach to 3,3-diphenylalanine is that the olefin substrate is tetra-substituted and therefore would be expected to have a much lower activity compared to substrates which have been previously examined. 

Oheme and co-workers investigated335 in an aqueous micellar system the asymmetric hydrogenation of a-amino acid precursors using optically active rhodium-phosphine complexes. Surfactants of different types significantly enhance both activity and enantioselectivity provided that the concentration of the surfactants is above the critical micelle concentration. The application of amphiphilized polymers and polymerized micelles as surfactants facilitates the phase separation after the reaction. Table 2 shows selected hydrogenation results with and without amphiphiles and with amphiphilized polymers for the reaction in Scheme 61.335... 

Scheme 24.9 Unsaturated a-amino acid derivatives prepared via chemoselective asymmetric hydrogenation.

Garbay reported the chemoselective reduction of a a-dehydrophenylala-nine substrate bearing a p-acrylate moiety [105]. Robinson et al. have also used a tandem, one-pot asymmetric hydrogenation-hydroformylation-cyclization approach to generate six- to eight-membered cyclic a-amino acids [136]. 

Asymmetric catalytic reduction reactions represent one of the most efficient and convenient methods to prepare a wide range of enantiomerically pure compounds (i.e. a-amino acids can be prepared from a-enamides, alcohols from ketones and amines from oximes or imines). The chirality transfer can be accomplished by different types of chiral catalysts metallic catalysts are very efficient for the hydrogenation of olefins, some ketones and oximes, while nonmetallic catalysts provide a complementary method for ketone and oxime hydrogenation. 

A fi-keto-bis-a-amino acid derivative 267 is a common precursor in these syntheses (Scheme 57), obtained by asymmetric Schollkopf alkylation <1994TL4091>, by Claisen condensation of glutamic acid precursors <1997TL6483, 1998JOC5937>, or by hydrogenation of bis-a,/3-unsaturated amino acid derivatives <2001TL3159>. 

Kubryk, M. and Hansen, K.B. Apphcation of the Asymmetric Hydrogenation of Enamines to the Preparation of a Amino Acid Pharmacophore. Tetrahedron Asymmetry 2006,17, 205-209. 

Scheme 9.4 Enantioselective synthesis of a-amino acids via catalytic asymmetric hydrogenation ofenamides.

Asymmetric Hydrogenation. Asymmetric hydrogenation with good enantio-selectivity of unfunctionalized prochiral alkenes is difficult to achieve.144 145 Chiral rhodium complexes, which are excellent catalysts in the hydrogenation of activated multiple bonds (first, in the synthesis of a-amino acids by the reduction of ol-N-acylamino-a-acrylic acids), give products only with low optical yields.144 146-149 The best results ( 60% ee) were achieved in the reduction of a-ethylstyrene by a rhodium catalyst with a diphosphinite ligand.150 Metallocene complexes of titanium,151-155 zirconium,155-157 and lanthanides158 were used in recent studies to reduce the disubstituted C—C double bond with medium enantioselectivity. 

T7fficient catalytic asymmetric hydrogenations have been achieved using an optically active phosphine complexed with rhodium (I, 2,3, 4, 5, 6, 7, 8). Through this process it is now possible to prepare a number of optically active a-amino acids from the corresponding unsaturated precursor without the usual resolution step by the following sequence. 

The rhodium-chiral phosphine catalyzed asymmetric hydrogenation of protected enam-ides, and other unsaturated amino acid derivatives (equation 85), gave almost 100% ee of the corresponding chiral a-amino acid derivative343,344. 

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