Novel cinchona alkaloid organocatalysts

Scheme 12.9 Synthesis of novel cinchona alkaloid organocatalysts with modified quinoline moiety. Reagents and conditions (a) Dt-BuAD, CH2CI2, rt, 2 h, 93% (b) PhNTf2, DMAP, CH2CI2 (c) 1. Pd(OAc)2, BINAP, Cs2C03, THF, Ph2C=NH, 2. citric acid, THF, H20 (d) 3,5-(CF3)2PhNCS, THF.

Wang and co-workers reported a novel class of organocatalysts for the asymmetric Michael addition of 2,4-pentandiones to nitro-olefms [131]. A screen of catalyst types showed that the binaphthol-derived amine thiourea promoted the enantiose-lective addition in high yield and selectivity, unlike the cyclohexane-diamine catalysts and Cinchona alkaloids (Scheme 77, Table 5). 

Recently, more efforts have been devoted to the design of novel bifunctional organocatalysts derived from natural cinchona alkaloids, which have been successfully applied in a number of asymmetric reactions. Deng et al. promoted the extensive... 

In 2005, Sons and coworkers introduced a novel bifunctional thiourea organocatalyst based on a Cinchona alkaloid for the asymmetric conjugate addition of nitromethane to tra s-chalcones. Using 10 mol% of thiourea 17, various electron-rich and electron-poor chalcones were well tolerated providing the desired adducts in high yields (80-94%) and very high enan-tioselectivities (95-96%) (Scheme 19.24). It has to be highlighted that... 

On the other hand, several cinchona alkaloid-derived primary amines have been successfully investigated as organocatalysts for asymmetric Michael additions of ketones to Michael acceptors. As an example, Lu et al. have described the first Michael addition of cyclic ketones to vinyl sulfone catalysed by a catalyst of this type, providing an easy access to chiral a-alkylated carbonyl compounds with high yields and enantioselectivities of up to 96% ee, albeit with moderate diastereoselectivities (<72% de), as shown in Scheme 1.21. This novel methodology was apphed to the synthesis of sodium cyclamate, an important compound in the artificial sweeteners industry. 

The concept of bifunctional catalysis as advanced for the natural cinchona alkaloids and cuprei(di)nes has resulted in the design and synthesis of a range of new cinchona derivatives. The major part of these novel organocatalysts are urea and thiourea cinchona derivatives together with cinchona alkaloids modified with, for example, a sulfonamide, squaramide, or guanidine group (Figure 6.8). 

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