Chiral compounds imines, reductive amination

It is known that electrochemical reduction of oximes in protic media occurs in two steps the N—O bond is first reduced to form an imine and the latter is then reduced to afford a primary amine1,29. Tallec has shown that the amine from oxime 33 can be trapped intramolecularly (equation 16)35. Interestingly, the SS diastereomer predominates the chiral pyrrolidine ring derivative serves to control the stereochemistry of formation of the new benzylic chiral center. Electrochemical reductive cross-coupling of O-methyl oximes with carbonyl compounds in isopropanol at a tin cathode affords adducts (equation 17) which can be reduced further to 2-amino alcohols36. In this fashion, menthone could... 

Stereospecific Reductive Amination of Carbonyl Compounds. Catalytic or chemical reduction of chiral imines derived from (1) often proceeds with high diastereoselectivity. Reductive removal of the a-methylbenzyl group yields chiral primary amines (eq 18 and 19). - ... 

Reductive alkylation with chiral substrates may afford new chiral centers. The reaction has been of interest for the preparation of optically active amino acids where the chirality of the amine function is induced in the prochiral carbonyl moiety 34,35). The degree of induced asymmetry is influenced by substrate, solvent, and temperature 26,27,28,29,48,51,65). Asymmetry also has been obtained by reduction of prochiral imines, using a chiral catalyst 44). Prediction of the major configurational isomer arising from a reductive alkylation can be made usually by the assumption that amine formation comes via an imine, not the hydroxyamino addition compound, and that the catalyst approaches the least hindered side (57). 

Optically active /3-ketoiminato cobalt(III) compounds based on chiral substituted ethylenedi-amine find use as efficient catalysts for the enatioselective hetero Diels Alder reaction of both aryl and alkyl aldehydes with l-methoxy-(3-(t-butyldimethylsilyl)oxy)-1,3-butadiene.1381 Cobalt(II) compounds of the same class of ligands promote enantioselective borohydride reduction of ketones, imines, and a,/3-unsaturated carboxylates.1382... 

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. 

Many other uses of a-sulfinyl carbanions are found in the literature, and in the recent past the trend has been to take advantage of the chirality of the sulfoxide group in asymmetric synthesis. Various ways of preparation of enantiopure sulfoxides have been devised (see Section 2.6.2) the carbanions derived from these compounds were added to carbonyl compounds, nitriles, imines or Michael acceptors to yield, ultimately, with high e.e. values, optically active alcohols, amines, ethers, epoxides, lactones, after elimination at an appropriate stage of the sulfoxide group. Such an elimination could be achieved by pyrolysis, Raney nickel or nickel boride desulfurization, reduction, or displacement of the C-S bond, as in the lactone synthesis reported by Casey [388]. 

The synthesis of enantiopure amino-functionalized compounds such as a- and (3-amino acids or nonfunctionalized amines can be envisaged by the use of aldehydes, ketones, a- or (3-keto acids, or derivatives thereof as substrates for imine formation followed by, for example, diastereoselective Strecker reactions, reductions, or organometallic addition reactions. In the literature, diastereoselective syntheses based on a large variety of chiral auxiliaries, such as a-arylethylamines,4... 

In this chapter, recent applications of (W)-phcnylglycine amide (1) in asymmetric synthesis are presented (Figure 25.2). The first section deals with diastereoselective Strecker reactions for the preparation of a-amino acids and derivatives, whereas the second section focuses on diastereoselective allylation of imines for preparation of enantiomerically pure homoallylamines. This latter class of compounds is a well-known intermediate for the synthesis of, for example, many types of amines, amino alcohols, and P-amino acids. The final section describes reduction of imines providing enantiomerically pure amines. (S)-3,3-Dimethyl-2-butylamine and (S)-l-aminoindane will be presented as leading examples. The results described in this chapter originate from a longstanding cooperation in the field of chiral technology development between DSM Pharma Chemicals and Syncom B.V. 

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