Chiral metal complexes aldol reactions

Other reviews deal with aldol additions of group 1 and 2 enolates,103 direct catalytic asymmetric aldol reactions catalysed by chiral metal complexes,104 the exploitation of multi-point recognition in catalytic asymmetric aldols,105 and recent progress in asymmetric organocatalysis of aldol, Mannich, Michael, and other reactions.106... 

The addition of an enolsilane to an aldehyde, commonly referred to as the Mukaiyama aldol reaction, is readily promoted by Lewis acids and has been the subject of intense interest in the field of chiral Lewis acid catalysis. Copper-based Lewis acids have been applied to this process in an attempt to generate polyacetate and polypropionate synthons for natural product synthesis. Although the considerable Lewis acidity of many of these complexes is more than sufficient to activate a broad range of aldehydes, high selectivities have been observed predominantly with substrates capable of two-point coordination to the metal. Of these, benzy-loxyacetaldehyde and pyruvate esters have been most successful. 

Further evidence for the intermediacy of a chiral metal enolate in the aldol process was provided in a subsequent publication (255). The authors found that this reaction could be equally well catalyzed by a Cu(I) complex (generated from the phosphine) and TB AT. Further, Tol-BINAPCuOf-Bu is also a competent catalyst for this reaction, underscoring the ability of the copper alkoxide to mediate desily-lation of the dienolsilane. The authors suggest that the dienolsilane effects the reduction of Cu(II) to Cu(I), although in light of the work of Lectka and co-workers (249) in this area, it seems equally likely that the phosphine mediates this reduction prior to introduction of the dienolsilane. Nevertheless, the intermediacy of a metal bound enolate seems assured. 

Owing to the high Lewis acidity the group 14 organometallic cations are polymerization catalysts par excellence. so Silanorbonyl cations and triethylsilyl arenium have been shown to be efficient catalysts for metal-free hydrosilylation reactions. Chiral silyl cation complexes with acetonitrile have been applied as cata -lysts in Diels Alder-type cyclization reactions °792 intramolecularly stabilized tetracoordinated silyl cations have been successfully used as efficient catalysts in Mukaiyama-type aldol reactions. 

Acyliron complexes with central chirality at the metal are obtained by substitution of a carbon monoxide with a phosphine ligand. Kinetic resolution of the racemic acyliron complex can be achieved by aldol reaction with (1 R)-( I (-camphor (Scheme 1.14) [41], Along with the enantiopure (R, c)-acyliron complex, the (Spe)-acyliron-camphor adduct is formed, which on treatment with base (NaH or NaOMe) is converted to the initial (SFe)-acyliron complex. Enantiopure acyliron complexes represent excellent chiral auxiliaries, which by reaction of the acyliron enolates with electrophiles provide high asymmetric inductions due to the proximity of the chiral metal center. Finally, demetallation releases the enantiopure organic products. 

Asymmetric lanthanide complexes derived from lanthanide triflates and a chiral bidentate sulfonamide ligand were applied to the Mukaiyama aldol reaction (Scheme 19) [299]. Enantiomeric excesses were moderate and the reaction proceeded best in CH2C12 solvent and with ytterbium as metal center. 

T. Hamada et al., Catalytic asymmetric aldol reactions in aqueous media using chiral bis-pyridino-18-crown-6-rare earth metal trillate complexes. J. Am. Chem. Soc. 125, 2989-2996 (2003)... 

Ito and coworkers found that chiral ferrocenylphosphine-silver(I) complexes also catalyze the asymmetric aldol reaction of isocyanoacetate with aldehydes (Sch. 26) [51]. It is essential to keep the isocyanoacetate at a low concentration to obtain a product with high optical purity. They performed IR studies on the structures of gold(I) and silver(I) complexes with chiral ferrocenylphosphine 86a in the presence of methyl isocyanoacetate (27) and found significant differences between the iso-cyanoacetate-to-metal coordination numbers of these metal complexes (Sch. 27). The gold(I) complex has the tricoordinated structure 100, which results in high ee, whereas for the silver(I) complex there is an equilibrium between the tricoordinated structure 101 and the tetracoordinated structure 102, which results in low enantioselectivity. Slow addition of isocyanoacetate 27 to a solution of the silver(I) catalyst and aldehyde is effective in reducing the undesirable tetracoordinated species and results in high enantioselectivity. 

Optically active l,l -binaphthols are among the most important chiral ligands of a variety of metal species. Binaphthol-aluminum complexes have been used as chiral Lewis acid catalysts. The l,T-binaphthyl-based chiral ligands owe their success in a variety of asymmetric reactions to the chiral cavity they create around the metal center [107,108]. In contrast with the wide use of these binaphthyls, the polymer-supported variety has been less popular. The optically active and sterically regular poly(l,l -bi-naphthyls) 96 have been prepared by nickel-catalyzed dehalogenating polycondensation of dibromide monomer 95 (Sch. 7) [109] and used to prepare the polybinaphthyl aluminum(III) catalyst 97 this had much greater catalytic activity than the corresponding monomeric catalyst when used in the Mukaiyama aldol reaction (Eq. 29). Unfortunately no enantioselectivity was observed in the aldol reaction. 

Evans synthesis of bryostatin 2 (113) also relied upon asymmetric aldol reactions for the introduction of most of the 11 stereocenters [58], At different points, the synthesis used control from an auxiliary, a chiral Lewis acid, chiral ligands on the enolate metal and substrate control from a chiral aldehyde. Indeed, this represents the current state of the art in the aldol construction of complex polyketide natural products. 

Their 3,3 -substituents are utilized not only for their steric bulk, but also for the coordination to metals. Yamamoto and coworkers employed a boron complex of 3,3 -bis(2-hydroxyphenyl) BINOL in the asymmetric Diels-Alder reaction of cyclopentadiene and acrylaldehyde (equation 70) . The ligand possesses two additional hydroxy groups and forms a helical structure on coordination. The catalyst is considered to function as a chiral Brpnsted acid and a Lewis acid. The complex was also used in the Diels-Alder reactions and aldol reactions of imines. Although addition of diethylzinc to aldehydes gives low ee using BINOL itself or its 3,3 -diphenyl derivative, the selectivity can be increased when coordinating groups are introduced at the 3,3 -positions. Katsuki and... 

Since the middle of the 198O s remarkable progress has been achieved in the development of asymmetric aldol reactions of silyl enolates. In the beginning of this evolution, chiral auxiliary-controlled reactions were extensively studied for this challenging subject [106]. As new efficient catalysts and catalytic systems for the aldol reactions were developed, much attention focused on catalytic enantiocontrol using chiral Lewis acids and transition metal complexes. Thus, a number of chiral catalysts realizing high levels of enantioselectivity have been reported in the last decade. 

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