Asymmetric catalyst for

The triazole 76, which is more accurately portrayed as the nucleophilic carbene structure 76a, acts as a formyl anion equivalent by reaction with alkyl halides and subsequent reductive cleavage to give aldehydes as shown (75TL1889). The benzoin reaction may be considered as resulting in the net addition of a benzoyl anion to a benzaldehyde, and the chiral triazolium salt 77 has been reported to be an efficient asymmetric catalyst for this, giving the products (/ )-ArCH(OH)COAr, in up to 86% e.e. (96HCA1217). In the closely related intramolecular Stetter reaction e.e.s of up to 74% were obtained (96HCA1899). 

Epoxide-hydrolases as asymmetric catalysts for ring opening of oxiranes 97T15617. 

The LLB catalysts requires at least 3.3 mol% of asymmetric catalyst for efficient nitro-aldol reactions, and the reactions are rather slow (first generation). Second-generation LLB catalysts are prepared by addition of 1 equiv of H20 and 0.9 equiv of w-BuLi. The second-generation-catalysts are more reactive than the first generation LLB as shown in Eq. 3.80. The proposed mechanism of asymmetric nitro-aldol reaction using these catalysts is presented in Scheme 3.20.128... 

This (R)-polyBINAP support, when treated with [Rh(cod)2]BF4 or [ RuC12(C6H6) 2]. afforded a heterogeneous asymmetric catalyst for hydrogenation of dehydroaminoacid derivatives and ketones.100 As an extension, a copolymer with BINOL and BINAP units randomly distributed... 

T. Arai, H. Sasai, K. Aoe, K. Okamura, T. Date, M. Shibasaki, A New Multifunctional Heterobimetallic Asymmetric Catalyst for Michael Additions and Tandem Michael-Aldol Reactions, Angew. Chem. Int. Ed Engl 1996, 35,104-106. 

Hatano, M. Ikeno, T Miyamoto, T Ishihara, K. Chiral lithium binaphtho-late aqua complex as a highly effective asymmetric catalyst for cyanohydrin synthesis. J. Am. Chem. Soc. 2005,127, 10116-10111. 

The metal complexes even with tropos ligands can thus be used as asymmetric catalysts for carbon-carbon bond-forming reactions in the same manner as atropos catalysts. The single diastereomer (7 )-32/(/ )-DABN can be employed as an activated asymmetric catalyst for the Diels-Alder reaction at room temperature (Table 8.11). The high chemical yield and enantioselectivity (62%, 94% ee) in the Diels-Alder reaction of ethyl glyoxylate with 1,3-cyclohexadiene are obtained... 

The enantiopure complex 35 has since been employed as an atropos asymmetric catalyst for a variety of synthetic transformations (Scheme 8.33)." In addition, the hetero Diels-Alder reaction of glyoxylate could also be catalyzed by enantiopure... 

The chiral f5-dialkylamino alcohol DAIB serves as an efficient asymmetric catalyst for the addition of organozinc reagents to aldehydes. The reaction of diethylzinc with benzaldehyde in the presence of 2 mol % of (2S)-(-)-DAIB to give (S)-1-phenyl-1-propanol in 89% ee is described in the procedure which follows. DAIB exhibits the... 

Asymmetric autocatalysis is defined as an enantioselective synthesis in which the chiral product acts as an asymmetric catalyst for its own production (equation 39). Asymmetric autocatalysis is an efficient method for the catalytic enantioselective automultiplication of a chiral molecule without the need for any other chiral auxiliary158. 

BINOL-Ti complexes (1) has been shown to serve as efficient asymmetric catalysts for the carbonyl addition reaction of allylic stannanes and silanes 152,53]. The addition reactions to glyoxylates of ( )-2-butenylsilane and -stannane proceed smoothly to afford the corresponding syn-product with high enantiomeric excess (Scheme 8C.21) [52]. 

The aldol reaction constitutes one of the most fundamental bond-construction processes in organic synthesis [56]. Therefore, much attention has been focused on the development of asymmetric catalysts for the Mukaiyama aldol reaction in recent years. 

Our proposed transition state model for this catalytic enantioselective cyanosilylation of ketone is shown as 35.30a The titanium acts as a Lewis acid to activate the substrate ketone, while the phosphine oxide acts as a Lewis base to activate TMSCN. The intramolecular transfer of the activated cyanide to the activated ketone should give the ( )-cyanohydrin in high selectivity. The successful results described above clearly demonstrate the practicality of our asymmetric catalyst for cyanosilylation of ketones. 

Considerable resources are being expended in the quest for new asymmetric catalysts for a wide variety of reactions (Chapter 12). In many cases, these catalysts are based on transition metals, where the ligands provide the chiral environment. However, as our understanding of biotransformations increases, coupled with our ability to produce mutant enzymes at scale, biocatalysts are beginning to become key components of our asymmetric synthetic toolbox (Chapter 19). 

The Ln-BINOL derivative complexes are efficient asymmetric catalysts for Michael reactions and the epoxidations of enones. However, as was mentioned above, almost racemic products are obtained in the case of the asymmetric nitroaldol reaction of 2 with 12. For this transformation, a new class of catalysts, heterobimetallic species, have been developed. 

A new type of lanthanoid complex, prepared from BINOL and SmCl3, served as an asymmetric catalyst for MPV reduction of aryl methyl ketones in the presence of molecular sieves. Moderate enantioselectivity was obtained.101... 

Knight RL, Leeper FJ (1998) Comparison of chiral thiazolium and triazolium salts as asymmetric catalysts for the benzoin condensation. J Chem Soc [Perkin 1] 1998 1891... 

Armstrong has developed a-fluoro-W-ethoxycarbonyltropinone 54 as an asymmetric catalyst for the enantio-selective epoxidation reaction 1-phenylcyclohexene oxide is produced in 97% yield and 69% ee (Scheme 20) <1998CC621>. Analogously, the use of a-acetoxy-8-oxabicyclo[3.2.1]octan-3-one 55 results in 71% yield and 98% ee (Scheme 20) <2001TA2779>. Tropinone catalyst 54 gives only low levels of enantioselectivity in the asymmetric epoxidation of dihydronaphthalene and an enol benzoate (Scheme 20) <2002JOC8610>. 

Application as a Component of an Asymmetric Catalyst. Amino alcohol (1) has proven to be a highly versatile ligand for use in asymmetric catalysts for a series of reactions. One of the most comprehensively studied uses is as an ox-azaborolidine derivative such as 8 for the asymmetric control of the reduction of ketones by borane. Although its use was first described with stoichiometric levels of 1 being employed for the reduction of both ketones and oximes, development of the system has delivered a catalytic method requiring only 5-10 mol % catalyst. Enantiomeric excesses of over 85% and as high as 96% have been achieved for a range... 

Other Applications. Chiral oxazaborolidines derived from ephedrine have also been used in asymmetric hydroborations, and as reagents to determine the enantiomeric purity of secondary alcohols. Chiral l,3,2-oxazaborolidin-5-ones derived from amino acids have been used as asymmetric catalysts for the Diels-Alder reaction,and the aldol reaction. ... 

Chiral alkyldihaloboranes are among the most powerful chiral Lewis acids. In general, however, because alkyldihaloboranes readily decompose to alkanes or alkenes as a result of protonolysis or /3-hydride elimination, it is difficult to recover them quantitatively as alkylboronic acids. Aryldichloroborane is relatively more stable and can be reused as the corresponding boronic acid. We have developed chiral aryldichlorobor-anes 23 bearing binaphthyl skeletons with axial chirality as asymmetric catalysts for the Diels-Alder reaction of dienes and a,/3-unsaturated esters (see, e.g., Eq. 37) [36]. 

As shown above, asymmetric catalysis of Diels-Alder reactions has been achieved by use of chiral titanium complexes bearing chiral diol ligands. Yamamoto has reported a chiral helical titanium complex derived from Ti(OPr )4 and a BINOL-derived tetraol ligand (Sch. 54) [134], The Diels-Alder products are obtained with uniformly high enantioselectivity, irrespective of the substituent pattern of a,/3-unsaturated aldehydes. Corey has also reported a new type of chiral titanium complex derived from an amino alcohol ligand (Sch. 55) [135]. The chiral titanium complex serves as an efficient asymmetric catalyst for the reaction of 2-bromoacrolein the Diels-Alder product is obtained with high enantioselectivity. 

Chiral titanium complexes are also employed as effective asymmetric catalysts for other carbon-carbon bond-forming reactions, for example addition of diketene (Sch. 66) [154c,162], Friedel-Crafts reaction (Sch. 67) [163] (Sch. 68) [164], iodocar-bocyclization (Sch. 69) [165], Torgov cyclization (Sch. 70) [166], and [2 -i- 1] cycloaddition (Sch. 71) [167]. Asymmetric functional group transformations can also be catalyzed by chiral titanium complexes. These transformations, for example the Sharpless oxidation [168] or hydride reduction [169] are, however, beyond the scope of this review because of space limitations. Representative results are, therefore, covered by the reference list. 

Catalytic asymmetric nitroaldol reactions promoted by LLB or its derivatives require at least 3.3 mol % asymmetric catalyst for efficient conversion, and even then the reactions are rather slow. To enhance the activity of the catalyst, consideration of the possible mechanism of catalytic asymmetric nitroaldol reactions is clearly a necessary prerequisite to formulation of an effective strategy. One possible mechanism of catalytic asymmetric nitroaldol reactions is shown at the top of Sch. 10. We strove to detect the postulated intermediate I by use of a variety of methods, but were unsuccessful, probably owing to the low concentrations of the intermediate, which we thought might be ascribed to the presence of an acidic OH group in close proximity. 

La-linked-BINOL complex 23 was introduced as a stable, storable, and reuse-able asymmetric catalyst for the Michael reaction [120]. Optimization of the reaction between dibenzyl malonate and 2-cyclohexene-1-one in DME afforded the Michael adduct in 94% yield and >99% ee. The extraordinary versatility of LnLB catalyts is also documented in the highly efficient Michael addition of thiols to a,y9-unsaturated carbonyl compounds [121] and tandem Michael-aldol reactions [122]. 

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