Reactions asymmetric aminoalkylation

The imines 12 (X = 4-CH3-QH4-SO2 (Ts), Ar, C02R, COR, etc.) preformed or generated in situ from N,0- or N,N-acetals or hemiacetals are another important class of Mannich reagents frequently used for diastereo- and/or enantioselective aminoalkylation reactions catalyzed by chiral Lewis acids (usually copper or palladium BINAP complexes such as 13). Among other things excellent results were obtained in the aminoalkylation of silyl enol ethers or ketene acetals [24], A typical example is the synthesis of Mannich bases 14 depicted in Scheme 5 [24b], Because of their comparatively high electrophilicity imines 12 could even be used successfully for the asymmetric aminoalkylation of unactivated alkenes 15 (ene reactions, see Scheme 5) [24h, 25], and the diastereo- and/or enantioselective aminoalkyla-... 

However, it could be shown that in principle simple imines can be used successfully as well for asymmetric aminoalkylation reactions catalyzed by chiral Lewis acids. The asymmetric allylation of simple imines 16 with allyltributylstannane (Scheme 6) catalyzed by the / -pinene derivative 17 [32a], for example furnished comparatively good results (for related asymmetric catalytic allylations of simple imines, see [32b-d]). Moreover, it was demonstrated on the basis of several Strecker-type syntheses [33-35] that catalysts such as the chiral aluminum complex 18 (Scheme 6) [33a—b] are also well suited for enantioselective aminoalkylations with simple imines. The mechanism indicated in Scheme 6 shows that the... 

The methodology of the catalytic asymmetric aldol reaction has been further extended to the aldol-type condensation of (isocyanomethyl)phosphonates (12) with aldehydes, providing a useful method for the synthesis of optically active (l-aminoalkyl)phosphonic acids, which are a class of biologically interesting phosphorous analogs of a-amino acids (Scheme 8B1.6) [21,22], Higher enantioselectivity and reactivity are obtained with diphenyl ester 12b than with diethyl ester 12a (Table 8B1.6). 

Nevertheless, the use of chirally modified Lewis acids as catalysts for enantioselective aminoalkylation reactions proved to be an extraordinary fertile research area [3b-d, 16]. Meanwhile, numerous publications demonstrate their exceptional potential for the activation and chiral modification of Mannich reagents (generally imino compounds). In this way, not only HCN or its synthetic equivalents but also various other nucleophiles could be ami-noalkylated asymmetrically (e.g., trimethylsilyl enol ethers derived from esters or ketones, alkenes, allyltributylstannane, allyltrimethylsilanes, and ketones). This way efficient routes for the enantioselective synthesis of a variety of valuable synthetic building blocks were created (e.g., a-amino nitriles, a- or //-amino acid derivatives, homoallylic amines or //-amino ketones) [3b-d]. 

For example, N-(2-hydroxyphenyl)imines 9 (R = alkyl, aryl) together with chiral zirconium catalysts generated in situ from binaphthol derived ligands were used for the asymmetric synthesis of a-amino nitriles [17], the diastereo- and/or enantioselective synthesis of homoallylic amines [18], the enantioselective synthesis of simple //-amino acid derivatives [19], the diastereo- and enantioselective preparation of a-hydroxy-//-amino acid derivatives [20] or aminoalkyl butenolides (aminoalkylation of triisopropylsilyloxyfurans, a vinylogous variant of the Mannich reaction) [21]. A good example for the potential of the general approach is the diastereo- and enantioselective synthesis of (2R,3S)-3-phenylisoserine hydrochloride (10)... 

The transamidation-like reactions of the 2-(aminoalkyl)-l,2-thiazetidin-3-one 1,1-dioxides 172 in the presence of (piperidinomethyl)-polystyrene give the ring-enlarged eight-membered products 13 in 42-87% yields (Equation 35 <1999HCA354>). To prove the exclusive attack of the amine at the carbonyl rather than at the sulfonyl group, compound 13 (R = Me) and its stmcture with an asymmetrically situated methyl substituent was then established by X-ray crystallography (see Section 14.08.3.1.5). 

The gold-catalyzed aldol reaction has been successfully applied to the asymmetric synthesis of (l-aminoalkyl)phosphonic acids, phosphonic analogs of a-amino acids (Scheme 2-57) [80, 81]. The reaction of (isocyanomethyl)phosphonates 65 with... 

The situation with regard to the (aminoalkyl)phosphonic acids is, however, completely different. Not only have many (aminoalkyl)phosphonic acids, either in the free state or as derivatives, generally esters, been resolved, but also many synthetic procedures have been adapted for potential asymmetric preferment. The latter will be considered under each individual type of reaction, but it is convenient to consider the problem of resolution separately. 

Aldol and imino-aldol reactions. A Yb complex prepared from YbfOTflj and a C -symmetric a,a -bistriflamidobibenzyl has been used in the Mukaiyama aldol reaction," resulting in moderate asymmetric induction. Imines are activated toward enol derivatives, such as ketene silyl ethers. iV-(a-aminoalkyl)benzotriazoles are suitable surrogates of imines. One-pot syntheses of p-amino esters and ketones can also be achieved. 

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