Organocatalysis enamine-based

Notz W, Tanaka F, Barbas CF (2004) Enamine-based organocatalysis with proline and diamines the development of direct catalytic asymmetric aldol, Mannich, Michael, and Diels-Alder reactions. Acc Chem Res 37(8) 580-591... 

Notz, W., Tanaka, F., Barbas, C. F., III. Enamine-Based Organocatalysis with Proline and Diamines The Development of Direct Catalytic Asymmetric Aldol, Mannich, Michael, and Diels-Alder Reactions. Acc. Chem. Res. 2004, 37, 580-591. 

Iminium-based organocatalysis is somewhat less explored than enamine-based organocatalysis and has been mostly used in the activation of a,/S-conjugated aldehydes and ketones. Therefore, this type of catalysis has unsurprisingly been the subject of a limited number of studies under the umbrella of the metal-organic cooperative catalysis concept. In 2011, the Cdrdova group [55] reported the first enantioselective and chemoselective /3-silyl addition to a./S-unsaturated aldehydes using copper salts and chiral pyrrolidine derivatives as catalysts. As proposed, the chiral secondary amine forms an iminium salt with... 

Enamine-Based Organocatalysis with Proline and Diamines The Development of Direct Catalytic Asymmetric Aldol ... 

Keywords Aldol, Direct, Ketone, Asymmetric catalysis, Enantioselective reaction, Diastereo-selectivity, 1,2-Diol, Aldehyde, Enamine, Lewis acid, Bronsted base, Organocatalysis, Bimetal-... 

The formation of covalent substrate-catalyst adducts might occur, e.g., by single-step Lewis-acid-Lewis-base interaction or by multi-step reactions such as the formation of enamines from aldehydes and secondary amines. The catalysis of aldol reactions by formation of the donor enamine is a striking example of common mechanisms in enzymatic catalysis and organocatalysis - in class-I aldolases lysine provides the catalytically active amine group whereas typical organocatalysts for this purpose are secondary amines, the most simple being proline (Scheme 2.2). 

Enamine catalysis often delivers valuable chiral compounds such as alcohols, amines, aldehydes, and ketones. Many of these are normally not accessible using established reactions based on transition metal catalysts or on preformed enolates or enamines, illustrating the complimentary nature of organocatalysis and metallocatalysis. 

One of the milestones in the development of organocatalysis is the intramolecular aldol reaction catalyzed by proline developed independently by two industrial research groups at Hoffmann-La Roche and Schering (Scheme 1.3). This reaction, also known as the Hajos-Parrish-Eder-Sauer-Wiechert reaction, was reported in 1971 and is based on the foundations of stoichiometric enamine chemistry by Stork and the mechanistic conclusions driven by Langebeck himself on some enzymatic reactions, and outlines for the first time the reversible formation of a nucleophilic enamine as the key intermediate participating in the catalytic cycle. 

The rediscovery of organocatalysis that has occurred over the past decade was easily applied to the Mannich reaction. Use of chiral amines 92 like proline or cinchonine readily convert carbonyl compound 90 to a chiral enamine that is then able to couple with imine 91. Chiral induction resulting from 92 gave rise to optically active Marmich bases 93 and 94 ... 

Rueping, M., Sunden, H., Hubener, L., Sugiono, E. (2012). Asymmetric oxidative Lewis base catalysis-unifying iminium and enamine organocatalysis with oxidations. Chemical Communications (Cambridge), 48, 2201-2203. 

Double Cascade Reactions Amine-based organocatalysis are often employed for these cascade reactions because they can present a dual-activation mode depending the system involved, via enamine or iminium catalysis. 

As an essential component to asymmetric organocatalysis, chiral, metal-free Bron-sted bases have mediated several types of C-C and C-X bond-forming reactions mediated by enamine and enolates. Brmsted bases (Figure 13.1) have the functional capacity to accept a hydrogen (or proton) from an acidic source or equivalent activated species. This proton transfer forms the basis of the key activation component to new-bond formation reactions. 

The rapid development of organocatalysis impels chemists to discover new synthetic methodologies. Many important transformations that could only be realized by transition metal catalysis can now be achieved via organocatalysis. In 2010, Kim and coworkers reported a novel C-H bond functionalization reaction via a tandem 1,5-hydride transfer/ring closure sequence. Based on the iminium-enamine cascade activation of catalyst 33, the fused tetrahydroquino-Unes 35 could be synthesized from substrates 34 with good stereoselectivity. This is the first example of an organocatalytic intramolecular redox reaction (Scheme 36.10) [16]. 

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