Thiourea derived catalysts Mannich reactions

Later, the same group succeeded in achieving a cascade Michael/nitro-Mannich/ acetalization reaction by the combination of covalent enamine catalysis and noncovalent bifunctional base/Br0nsted acid catalysis [32]. The fuUy substituted piperidines with diverse substitution patterns were prepared efficiently starting from simple aliphatic aldehydes, Ts-protected imines, and trani -P-nitro alkenes (Scheme 9.36). This finding effectively incorporated prolinol silyl ether-catalyzed Michael addition of aldehyde 65 to nitroalkene 75 and valine-derived bifunctional thiourea-mediated nitro-Mannich reaction of y-nitro aldehyde 106 to imine 105 in the cascade process, providing a complementary contribution to the well-known single catalyst-promoted triple cascade reactions and two catalyst-promoted reaction cascades. 

In Ught of the recent developments in thiourea, diol, and phosphoric-acid-mediated catalysis, far fewer studies have focused on the use of chiral carboxyhc acids as suitable hydrogen bond donors. To this end, Mamoka synthesized binaphthyl-derived dicarboxylic acid 49 which catalyzes the asymmetric Mannich reaction of N-Boc aryl imines and tert-diazoacetate (Scheme 5.65) [120]. The authors postulate that catalytic achvity is enhanced by the presence of an addihonal car-boxyhc acid moiety given that use of 2-napthoic acid as catalyst provided only trace amounts of product... 

The use of bifunctional thiourea-substituted cinchona alkaloid derivatives has continued to gamer interest, with the Deng laboratory reporting the use of a 6 -thiourea-substituted cinchona derivative for both the Mannich reactions of malo-nates with imines [136] and the Friedel-Crafts reactions of imines with indoles [137]. In both reports, a catalyst loading of 10-20 mol% provided the desired products in almost uniformly high yields and high enantioselectivities. Thiourea-substituted cinchona derivatives have also been used for the enantioselective aza-Henry reactions of aldimines [138] and the enantioselective Henry reactions of nitromethane with aromatic aldehydes [139]. 

In addition to chiral PTCs, cinchona-based thioureas have also been proved to serve as catalysts for nitro-Mannich reactions. In 2006, Ricci and coworkers first reported that the quinine-based thiourea 40 (20mol%) can catalyze the aza-Henry reaction between nitromethane and the N-protected imines 93 derived from aromatic aldehydes [40]. N-Boc-, N-Cbz-, and N-Fmoc protected imines gave the best results in terms of the chemical yields and enantioselectivities (up to 94% ee at —40°C) (Scheme 8.30). 

More recently, Pihko introduced bifunctional tertiary amine-thioureas 26 and 27 for the Mannich reaction of Boc-imines with malonates. ° Dimethylamino-tertiary amine thiourea 26 proved ideal for aliphatic imines, while the Cinchona derivative 27 provided the best results for aromatic substrates. Catalyst loadings as low as 1 mol% could be employed providing the products in high yields and excellent enantioselec-tivities (Scheme 19.34). Notably, both catalysts presented cooperative assistance via intermolecular hydrogen bonding, as first shown by Smith in 2009. ... 

The dual activation mode of the aforementioned cinchona alkaloid-derived thiourea catalysts proved to be highly effective in catalyzing the asynunetric Mannich reaction, among other transformations. These findings prompted the development of new, more simple bifunctional chiral catalysts that are predominately based on tra 5 -l,2-diaminocy-clohexane. For example, the application of the thiourea catalyst 120, which was developed by Takemoto and coworkers, afforded upon the reaction of Af-Boc-protected imines with diethyl malonate the desired chiral amines in good chemical yields (up to 91%) and enantioselectivities (98% ee) (Scheme 11.23) [81]. The catalytic mechanism presumably involves deprotonation and coordination of the active carbonyl compound by the chiral tertiary amine moiety. The formed enolate then attacks the si-face of the... 

It must be noted that chiral thiourea catalysts have been used earlier to catalyze the asymmetric Mannich reaction. Jacobsen and Wenzel reported the enantioselective synthesis of A-Boc-protected p-amino acids from silyl ketene acetals and A-Boc-protected imines using the thiourea catalyst 123 (Scheme 11.24). Here, the chiral thiourea-derived Brpnsted acid catalyst (the application of chiral Brpnsted acids in the... 

Later, a highly enantioselective Mannich reaction employing glycine Schiff base 145 as nucleophile was described by Zhang et al., in which a-amido sulfones 142a participated very well as precursors (Scheme 2.41). With dihydroquinine-derived thiourea 130c as catalyst, this Mannich reaction provided access to optically active a,p-diamino acid derivatives 146 with up to >99 1 dr and >99% ee [59]. 

Enders et al. developed an asymmetric synthesis of polyfiinctionalized pyrrolidines based on Mannich-Michael cascade strategy (Scheme 2.42). Under the promotion of 10mol% thiourea catalyst 140b, y-malonate-substituted a,P-unsaturated esters 149 and N-protected aryl aldimines 148 underwent Mannich reaction to afford chiral amine intermediates, which then underwent an intramolecular aza-Michael reaction to yield pyrrolidine derivatives 150 with moderate to good enantioselectivities [60]. 

Cyclohexanediamine-derived amine thiourea 70, which provided high enantio-selectivities for the Michael addition [77] and aza-Henry reactions [78], showed poor activity in the MBH reaction. This fact is not surprising when one considers that a chiral urea catalyst functions by fundamentally different stereoinduction mechanisms in the MBH reaction, and in the activation of related imine substrates in Mannich or Streclcer reactions [80]. In contrast, the binaph-thylamine thiourea 71 mediated the addition of dihydrocinnamaldehyde 74 to cyclohexenone 75 in high yield (83%) and enantioselectivity (71% ee) (Table 5.6, entry 2) [79]. The more bulky diethyl analogue 72 displayed similar enantioselectivity (73% ee) while affording a lower yield (56%, entry 3). Catalyst 73 showed only low catalytic activity in the MBH reaction (18%, entry 4). 

On the other hand, there is a report regarding a cascade Michael reaction followed by intramolecular nitro-Mannich (aza-Henry) reaction occurring between imides derived from diethyl aminomalonate and nitrostyrenes using thiourea 68a as catalyst (Scheme 7.63). This reaction results in a formal [3 + 2] cycloaddition between these two reagents, with this aminomalonate-derived... 

Later Schaus and co-workers used the cinchona alkaloid-derived thiourea catalyst 60 to catalyze the nucleophilic addition of both nitroalkanes (not shown) and dimethyl malonate to the Al-carbamoyl protected imines 46b, 61a-d to produce the corresponding Mannich adducts 62 in excellent yields and high enantioselectivities (Scheme 5.30) [41], The level of selectivity observed in these reactions is indicative of a catalyst-associated complex with a high degree of coordination. Modelling... 

In 2010, Monge et al. reported a one-pot tandem reaction by combining bifunctional thiourea and Au complex [77], affording dihydropynole derivatives in moderate yields and high enantioselectivities. The reaction was based on a bifunctional thiourea-catalyzed Mannich-type reaction and a subsequent Au-catalyzed alkyne hydroamination and isomerization of propargylated malononitrile and N-Boc-protected imines (Scheme 9.72). Notably, acidic additive proved cracial to prevent deactivation of the gold catalyst and enhance the reactivity and selectivity. 

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