Enamine catalysis reactions

A number of products in which one of the naphthalene rings has been reduced have interesting pharmacological properties. Reaction of tetralone 30 with dimethylamine under TiCl catalysis produces the corresponding enamine (31). Reaction with formic acid at room temperature effects reduction of the... 

Mannich Reactions Expanding the concept of enamine catalysis outside... 

A major advancement for the subfield of enamine catalysis was achieved with the identification of aldehydes as useful donors for similar Mannich reactions.In particular, the addition of mono- or disubstituted aldehydes to ketoi-mines or aldimines, respectively, represents an elegant and highly efficient approach to the enantioselective construction of quaternary a-amino acids (Scheme 11A one-pot, three-component variant of the aldehyde Mannich reaction has also been recently disclosed (Scheme i 296-300... 

Diels-Alder Reactions The organocatalytic Diels-Alder reaction of a,P-unsaturated carbonyl compounds can be performed either via iminium (see Section 11.3) or enamine catalysis. The first highly selective enamine-promoted cycloaddition reaction was reported by Jprgensen and coworkers, who developed an amine-catalyzed inverse-electron-demand hetero-Diels-Alder (HDA) reaction (Scheme ll.lOa). ... 

Enantioselective -Functionalization of Aldehydes and Ketones The direct and enantiosective functionalization of enolates or enolate equivalents with carbon-, nitrogen-, oxygen-, sulfur- or halogen-centered electrophiles represents a powerful transformation of chemical synthesis and of fundamental importance to modem practitioners of asymmetric molecule constmction. Independent studies from List, J0rgensen, Cordova, Hayashi, and MacMiUan have demonstrated the power of enamine catalysis, developing catalytic enantioselective reactions such as... 

Abstract The reversible reaction of primary or secondary amines with enolizable aldehydes or ketones affords nncleophilic intermediates, enamines. With chiral amines, catalytic enantioselective reactions via enamine intermediates become possible. In this review, structure-activity relationships and the scope as well as cnrrent limitations of enamine catalysis are discnssed. 

This catalytic enamine formation is limited to aldehydes and ketones as starting materials - it does not appear to be possible to prepare corresponding enamines , i.e. A,0-ketene acetals, from esters in this fashion. Nevertheless, the preparation of simple, reactive nucleophiles from normally electrophilic species, aldehydes and ketones, in a catalytic fashion sounds highly attfactive. Furthermore, the catalytic nature of these reactions allows the use of chiral amines, and the further possibility that these reactions can be rendered enantioselective. Enamines react readily with a wide variety of electrophiles, and the range of reactions that can be catalyzed by enamine catalysis is summarized in Scheme 2. 

The development of enamine catalysis parallels that of iminium catalysis (Scheme 3) [24], Like iminium catalysis, the concept took a long time to mature, and also required a key discovery - the discovery of intermolecular proline-catalyzed aldol reactions by List and coworkers in 2000 [23] - to set the field in motion. The timeline of historical developments of enamine catalysis is outlined in Scheme 4. 

The word enamine was coined in 1927 by Wittig [27], However, at that time, enamines were usually not considered as reactive intermediates. An early example of enamine catalysis that was not explicitly recognized as enamine-based reaction was the reaction of isatin with ketone nucleophiles (acetone and acetophenone), first pnblished by Lindwall and coworkers in 1932 [28, 31]. Later, the interconversion of imininm ions and enamines in enzymatic reactions was recognized by Westheimer [32, 354]. The first person to propose a modem enamine-based... 

In the following discussion, key reactions of enamine catalysis are summarized. Present limitations of each method are also discussed. For more detailed treatment of the reactions, the original publications as well as recent comprehensive reviews [8-23] should be consulted. 

The delicateness of the aldol protocol has perhaps been one of the factors why enamine catalysis of the aldol reaction did not emerge nntil the 1970s. The Hajos-Parrish-Eder-Sauer-Wiechert reaction [30] (Scheme 16) was an important early example of an intramolecular enamine-catalyzed aldol reaction. However, it was not nntil 2000 when List, Barbas and Lemer demonstrated that the same reaction can also be performed in an intermolecular fashion, using proline as a simple enamine catalyst [26]. 

A range of nitrogen, phosphorus, chalcogen (O, S, Se) and halogen electrophiles react with enamines, resulting in a net a-functionalization of the carbonyl compound. In the past five years, all of these reaction variants have been subjected to asymmetric enamine catalysis, with excellent results. 

Over the past eight years, enantioselective enamine catalysis has expanded in scope more rapidly than perhaps any other field of asymmetric catalysis. From a handful of examples within the realm of aldol catalysis known in the beginning of 2000, the field enamine catalysis now comprises more than 50 different reactions, nearly 1000 different catalysts, and more than 1000 examples Still, major challenges remain to be solved. 

Barbas, one of the pioneers of enamine catalysis, has incorporated iminium ion intermediates in complex heterodomino reactions. One particularly revealing example that uses the complementary activity of both iminium ion and enamine intermediates is shown in Fig. 12 [188]. Within this intricate catalytic cycle the catalyst, L-proline (58), is actively involved in accelerating two iminium ion catalysed transformations a Knoevenagel condensation and a retro-Michael/Michael addition sequence, resulting in epimerisation. 

Recently, List has described a cascade reaction promoted by phosphoric acid 1 in combination with stoichiometric amounts of achiral amine, which transforms various 2,6-diketones to the corresponding ds-cyclohexylamines (Scheme 5.28) [50]. This three-step process involves initial aldolization via enamine catalysis to give conjugate iminium ion intermediate A. Next, asymmetric conjugate reduction followed by a diastereoselective 1,2 hydride addition completes the catalytic cycle. 

A bifunctional mechanism involving enamine catalysis [55, 58, 77] was clearly indicated in the Michael reactions promoted by catalyst 101. The observed... 

A simple method for the direct catalytic allylic alkylation of aldehydes and cyclic ketones has been developed.26 The direct catalytic highly chemo- and regio-selective intermolecular a-allyhc alkylation reaction has been mediated by an unprecedented combination of palladium and enamine catalysis which furnishes a-allylic alkylated aldehydes and cyclic ketones in high yield. 

In this transformation two new C-C-rr-bonds are formed from three different components. The enantioselectivity of this reaction is generally low (< 5%). With cyclic ketones the corresponding products were obtained as single diastereomers. It is proposed that this reaction involves a Knoevenagel-hetero-Diels-Alder sequence where proline utilizes both iminium and enamine catalysis (Scheme 9.20). 

Iminium catalysis directly utilizes the higher reactivity of the iminium ion in comparison to the carbonyl species and facilitates Knoevenagel-type condensations, cyclo- and nucleophilic additions, and cleavage of cr-bonds adjacent to the a-carbon. Enamine catalysis on the other hand involves catalytically generated enamine intermediates that are formed via deprotonation of an iminium ion, and react with various electrophiles or undergo pericyclic reactions. ... 

Enamine catalysis involves a catalytically generated enamine intermediate that is formed via deprotonation of an iminium ion and that reacts with various electrophiles or undergoes pericyclic reactions. The first example of asymmetric enamine catalysis is the Hajos-Parrish-Eder-... 

Scheme 5. Enamine catalysis of nucleophilic addition- and substitution reactions (arrows may be considered equilibria)...

Enamine catalysis using proline or related catalysts has now been applied to both intermolecular and intramolecular nucleophilic addition reactions with a variety of electrophiles. In addition to carbonyl compounds (C = O), these include imines (C = N) in Mannich reactions (List 2000 List et al. 2002 Hayashi et al. 2003a Cordova et al. 2002c ... 

Scheme 6. Enamine catalysis of nucleophilic addition reactions...

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. 

Selected recent developments in the area of asymmetric organocatalysis in our laboratory have been briefly summarized. Enamine catalysis, Brpnsted acid catalysis, and iminium catalysis turn out to be powerful new strategies for organic synthesis. Using Hantzsch ester as the hydride source, highly enantioselective transfer hydrogenantion reactions have been developed. We have also developed an additional new con-... 

List B (2004) Enamine catalysis is a powerful strategy for the catalytic generation and use of carbanion equivalents. Acc Chem Res 37 548-557 List B, Hoang L, Martin HJ (2004) New mechanistic studies on the proline-catalyzed aldol reaction. Proc Natl Acad Sci USA 101 5839-5842... 

S.C. PanandB. List s paper spans the whole field of current organocat-alysts discussing Lewis and Brpnsted basic and acidic catalysts. Starting from the development of proline-mediated enamine catalysis— the Hajos-Parrish-Eder-Sauer-Wiechert reaction is an intramolecular transformation involving enamine catalysis—into an intermolecular process with various electrophilic reaction partners as a means to access cY-functionalized aldehydes, they discuss a straightforward classification of organocatalysts and expands on Brpnsted acid-mediated transformations, and describe the development of asymmetric counteranion-directed catalysis (ACDC). 

As discussed above, all of the cinchona-based quaternary ammonium salts used as catalysts gave only poor to moderate diastereoselectivities and enantioselectivities for direct aldol reactions. Quite recently, a highly enantioselective, catalytic, direct aldol reaction was realized by adopting the enamine catalysis approach [12], in which 9-amino-epi-cinchona alkaloids are employed as aminocatalysts [13, 14]. 

In 2007, Connon and McCooey developed highly efficient, asymmetric syn-selective addition reactions of enolizable carbonyl compounds to nitroolefins by adopting the enamine catalysis approach [48]. The 9-epi-amino cinchona alkaloid derivative (160,9 -epi-DHQDA) as an aminocatalyst promoted the addition ofa variety... 

Chen and coworkers have reported a new domino Michael-Michael addition reaction between a,a-dicyanoalkene [26] derived from cyclohexanone and benzyli-deneacetone, resulting in a stepwise [4 + 2]-type cycloaddition to afford almost enantiopure bicyclic adduct 15. In contrast to the completely inert function of secondary ammonium salt, a primary amine, 9-amino-9-deoxyepiquinine lo [27], in combination with trifluoroacetic acid, was found to be highly efficient in the activation of the a, 3-unsaturated ketone by tandem iminium-enamine catalysis (Scheme 10.21) [28],... 

A variety of a,a-dicyanoalkenes derived from aryl ketones have also been extensively explored under the same catalytic conditions, and in general the vinylogous Michael adducts were obtained due to the steric hindrance in the following enamine catalysis by primary amine lo [28]. Nevertheless, an interesting domino Michael-Michael-retro-Michael reaction was observed for a,a-dicyanoalkenes derived from acetophenone and propiophenone, giving a facile process to chiral 2-cyclohexen-l-one derivatives. It was noteworthy that a kinetic resolution was observed in the intramolecular Michael addition step (Scheme 10.22). 

One of the most studied processes is the direct intermolecular asymmetric aldol condensation catalysed by proline and primary amines, which generally uses DMSO as solvent. The same reaction has been demonstrated to also occur using mechanochemical techniques, under solvent-free ball-milling conditions. This chemistry is generally referred to as enamine catalysis , since the electrophilic substitution reactions in the a-position of carbonyl compounds occur via enamine intermediates, as outlined in the catalytic cycle shown in Scheme 1.1. A ketone or an a-branched aldehyde, the donor carbonyl compound, is the enamine precursor and an aromatic aldehyde, the acceptor carbonyl compound, acts as the electrophile. Scheme 1.1 shows the TS for the ratedetermining enamine addition step, which is critical for the achievement of enantiocontrol, as calculated by Houk. ... 

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