Mannich reaction, catalytic enantioselective

The same research group also developed an enantioselective catalytic Mannich reaction using a phosphoglycine benzophenone imine as a Man-nich donor, promoted by the 2-picolyl N-oxide PTC catalyst 48h/ The new reaction represented an efficient method for the preparation of ot,p-diami-nophosphonic acids (94). Furthermore, they synthesised ot-alkylidene-p-amino carbonyl derivatives, usually named as aza-Morita-Baylis-Hillman (aza-MBH) adducts (95), by an asymmetric Mannich reaction using the N-(2-methoxybenzyl) quininium catalyst 48g followed by Horner olefination (Scheme 16.31). ... 

Wenzel AG, Jacobsen EN (2002) Asymmetric catalytic Mannich reactions catalyzed by urea derivatives enantioselective synthesis of beta-aryl-beta-amino acids. J Am Chem Soc 124 12964-12965 Wertz PW, Miethke MC, Long SA, Stauss JS, Downing DT (1985) The composition of the ceramides from human stratum comeum and from comedones. J Invest Dermatol 84 410—412... 

In this review we will attempt to highlight the most important contributions toward the realization of a catalytic, enantioselective, vinylogous Mannich reaction and show the current state of the art. This chapter is organized in such a way that vinylogous Mannich reactions of preformed silyl dienolates in Mukaiyama type reactions will be discussed first followed by direct vinylogous Mannich reactions of unmodified substrates. 

In 2008 our group reported the first example of a catalytic, enantioselective, vinylogous Mannich reaction of acyclic silyl dienolate 30 with imines (Table 5.5) [14]. 

The catalytic, enantioselective, vinylogous Mannich reaction has recently emerged as a very powerful tool in organic synthesis for the assembly of highly functionalized and optically enriched 6 amino carbonyl compounds. Two distinctly different strategies have been developed. The first approach calls for the reaction of preformed silyl dienolates as latent metal dienolates that react in a chiral Lewis acid or Bronsted acid catalyzed Mukaiyama type reaction with imines. Alternatively, unmodified CH acidic substrates such as a,a dicyanoalkenes or 7 butenolides were used in vinylo gous Mannich reactions that upon deprotonation with a basic residue in the catalytic system generate chiral dienolates in situ. 

Marques, M.M.B. (2006) Catalytic enantioselective cross-Mannich reaction of aldehydes. Angewandte Chemie — International Edition, 45, 348-352. 

Scheme 11.27 First catalytic, enantioselective reductive Mannich reaction of ketimine [45],...

The Mannich reaction and its variants have been reviewed, mainly focussing on asymmetric catalysis thereof. Catalytic, enantioselective, vinylogous Mannich reactions have also been reviewed, covering both direct and silyl dienolate methods. Another review surveys Mannich-type reactions of nitrones, oximes, and hydrazones. A pyrrolidine-thiourea-tertiary amine catalyses asymmetric Mannich reaction of N-Boc-imines (e.g. Ph-Ch=N-Boc) with ethyl-4-chloro-3-oxobutanoate to give highly functionalized product (16). Addition of triethylamine leads to one-pot intramolecular cyclization to give an 0-ethyl tetronic acid derivative (17). ... 

Deiana L, Zhao GL, Dziedzic P, Rios R, Vesely J, Ekstroem J, Cordova A. One-pot highly enantioselective catalytic Mannich-type reactions between aldehydes and stable a-amido sulfones asymmetric synthesis of 3-amino aldehydes and (3-amino acids. Tetrahedron Lett. 2010 51 (2) 234-237. 

Kobayashi and his team have utilized a catalytic system similar to that used in their development of a Zr-catalyzed Mannich reaction (Schemes 6.27—6.29) to develop a related cycloaddition process involving the same imine substrates as used previously (Scheme 6.35) [105]. As the representative examples in Scheme 6.35 demonstrate, good yields and enantioselectivities (up to 90% ee) are achieved. Both a less substituted version of the Danishefsky diene (—> 110) and those that bear an additional Me group (e. g.— 111) can be utilized. Also as before, these workers propose complex 89, bearing two binol units, to be the active catalytic species. 

The studies summarized above clearly bear testimony to the significance of Zr-based chiral catalysts in the important field of catalytic asymmetric synthesis. Chiral zircono-cenes promote unique reactions such as enantioselective alkene alkylations, processes that are not effectively catalyzed by any other chiral catalyst class. More recently, since about 1996, an impressive body of work has appeared that involves non-metallocene Zr catalysts. These chiral complexes are readily prepared (often in situ), easily modified, and effect a wide range of enantioselective C—C bond-forming reactions in an efficient manner (e. g. imine alkylations, Mannich reactions, aldol additions). 

Systematic investigations of the catalyst structure-enantioselectivity profile in the Mannich reaction [72] led to significantly simplified thiourea catalyst 76 lacking both the Schiff base unit and the chiral diaminocyclohexane backbone (figure 6.14 Scheme 6.88). Yet, catalyst 76 displayed comparable catalytic activity (99% conv.) and enantioselectivity (94% ee) to the Schiff base catalyst 48 in the asymmetric Mannich reaction of N-Boc-protected aldimines (Schemes 6.49 and 6.88) [245]. This confirmed the enantioinductive function of the amino acid-thiourea side chain unit, which also appeared responsible for high enantioselectivities obtained with catalysts 72, 73, and 74, respectively, in the cyanosilylation of ketones (Schemes 6.84 and 6.85) [240, 242]. 

Asymmetric Mannich reactions provide useful routes for the synthesis of optically active p-amino ketones or esters, which are versatile chiral building blocks for the preparation of many nitrogen-containing biologically important compounds [1-6]. While several diastereoselective Mannich reactions with chiral auxiliaries have been reported, very little is known about enantioselective versions. In 1991, Corey et al. reported the first example of the enantioselective synthesis of p-amino acid esters using chiral boron enolates [7]. Yamamoto et al. disclosed enantioselective reactions of imines with ketene silyl acetals using a Bronsted acid-assisted chiral Lewis acid [8]. In all cases, however, stoichiometric amounts of chiral sources were needed. Asymmetric Mannich reactions using small amounts of chiral sources were not reported before 1997. This chapter presents an overview of catalytic asymmetric Mannich reactions. 

In 1997, the first truly catalytic enantioselective Mannich reactions of imines with silicon enolates using a novel zirconium catalyst was reported [9, 10]. To solve the above problems, various metal salts were first screened in achiral reactions of imines with silylated nucleophiles, and then, a chiral Lewis acid based on Zr(IV) was designed. On the other hand, as for the problem of the conformation of the imine-Lewis acid complex, utilization of a bidentate chelation was planned imines prepared from 2-aminophenol were used [(Eq. (1)]. This moiety was readily removed after reactions under oxidative conditions. Imines derived from heterocyclic aldehydes worked well in this reaction, and good to high yields and enantiomeric excesses were attained. As for aliphatic aldehydes, similarly high levels of enantiomeric excesses were also obtained by using the imines prepared from the aldehydes and 2-amino-3-methylphenol. The present Mannich reactions were applied to the synthesis of chiral (3-amino alcohols from a-alkoxy enolates and imines [11], and anti-cc-methyl-p-amino acid derivatives from propionate enolates and imines [12] via diastereo- and enantioselective processes [(Eq. (2)]. Moreover, this catalyst system can be utilized in Mannich reactions using hydrazone derivatives [13] [(Eq. (3)] as well as the aza-Diels-Alder reaction [14-16], Strecker reaction [17-19], allylation of imines [20], etc. 

It was also reported that diastereo- and enantioselective Mannich reactions of activated carbonyl compounds with a-imino esters were catalyzed by a chiral Lewis acid derived from Cu(OTf)2 and a bisoxazoline (BOX) ligand [31] [(Eq. (6)]. Catalytic enantioselective addition of nitro compounds to imines [32], and aza-Henry reactions of nitronates with imines [33] also proceeded under similar reaction conditions. 

It was reported that proline catalyzed the direct catalytic asymmetric Mannich reactions of hydroxyacetone, aldehydes, and aniline derivatives [(Eq. (10)] [40-44]. Not only aromatic aldehydes but also aliphatic aldehydes worked well in this reaction, and good to excellent enantioselectivity and moderate to excellent yields were observed. Mannich reactions of glyoxylate imines with aldehydes or ketones were also successfully performed [45,46]. 

An important feature of this reaction is that in contrast to most other catalytic asymmetric Mannich reactions, a-unbranched aldehydes are efficient electrophiles in the proline-catalyzed reaction. In addition, with hydroxy acetone as a donor, the corresponding syn-l, 2-aminoalcohols are furnished with high chemo-, regio-, diastereo-, and enantioselectivities. The produced ketones 14 can be further converted to 4-substituted 2-oxazolidinones 17 and /i-aminoalcohol derivatives 18 in a straightforward manner via Baeyer-Villiger oxidation (Scheme 9.4) [5]. 

Trost and coworkers recently reported that these dinuclear zinc complexes catalyze Mannich reactions with unmodified aromatic hydroxy ketones as donors with excellent enantioselectivity [18]. Mannich-type reactions between an N-para-meth-oxyphenyl (PMP)-protected a-ethyl glyoxalate and hydroxyacetophenone in the presence of a catalytic amount of catalyst 5a afford the desired N-PMP protected amino acid derivative in 76 % yield with a dr of 7 1 and 95 % ee (Eq.5). 

The similarity between mechanisms of reactions between proline- and 2-deoxy-ribose-5-phosphate aldolase-catalyzed direct asymmetric aldol reactions with acetaldehyde suggests that a chiral amine would be able to catalyze stereoselective reactions via C-H activation of unmodified aldehydes, which could add to different electrophiles such as imines [36, 37]. In fact, proline is able to mediate the direct catalytic asymmetric Mannich reaction with unmodified aldehydes as nucleophiles [38]. The first proline-catalyzed direct asymmetric Mannich-type reaction between aldehydes and N-PMP protected a-ethyl glyoxylate proceeds with excellent chemo-, diastereo-, and enantioselectivity (Eq. 9). 

The phase-transfer-catalyzed direct Mannich reaction of 28 with a-imino ester 64 was achieved with high enantioselectivity by using 32e as catalyst (Scheme 4.23) [63]. This method enables the catalytic asymmetric synthesis of differentially protected 3-aminoaspartate, a nitrogen analogue of dialkyl tartrate, the util-... 

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