Mukaiyama aldol reactions, asymmetric catalysis

Carreira, E. M. Mukaiyama aldol reaction. Comprehensive Asymmetric Catalysis /-///1999, 3, 997-1065. 

Asymmetric Lewis-Acid Catalyzed. Another important advance in aqueous Mukaiyama aldol reaction is the recent success of asymmetric catalysis.283 In aqueous ethanol, Kobayashi and co-workers achieved asymmetric inductions by using Cu(OTf)2/chiral >A(oxazoline) ligand,284 Pb(OTf)2/chiral crown ether,285 and Ln(OTf)3/chiral Mv-pyridino-18-crown-6 (Eq. 8.105).286... 

Although in the recent years the stereochemical control of aldol condensations has reached a level of efficiency which allows enantioselective syntheses of very complex compounds containing many asymmetric centres, the situation is still far from what one would consider "ideal". In the first place, the requirement of a substituent at the a-position of the enolate in order to achieve good stereoselection is a limitation which, however, can be overcome by using temporary bulky groups (such as alkylthio ethers, for instance). On the other hand, the ( )-enolates, which are necessary for the preparation of 2,3-anti aldols, are not so easily prepared as the (Z)-enolates and furthermore, they do not show selectivities as good as in the case of the (Z)-enolates. Finally, although elements other than boron -such as zirconium [30] and titanium [31]- have been also used succesfully much work remains to be done in the area of catalysis. In this context, the work of Mukaiyama and Kobayashi [32a,b,c] on asymmetric aldol reactions of silyl enol ethers with aldehydes promoted by tributyltin fluoride and a chiral diamine coordinated to tin(II) triflate... 

Carreira EM (1999) Mukaiyama aldol reaction. In Jacobsen EN, Pfaltz A, Yamamoto H (eds) Comprehensive asymmetric catalysis, vol III. Springer, Berlin Hidelberg New York, p 997... 

Studies of catalytic asymmetric Mukaiyama aldol reactions were initiated in the early 1990s. Until recently, however, there have been few reports of direct catalytic asymmetric aldol reactions [1]. Several groups have reported metallic and non-metallic catalysts for direct aldol reactions. In general, a metallic catalysis involves a synergistic function of the Bronsted basic and the Lewis acidic moieties in the catalyst (Scheme 2). The Bronsted basic moiety abstracts an a-pro-ton of the ketone to generate an enolate (6), and the Lewis acidic moiety activates the aldehyde (3). 

Chiral sulfoximines liganded to copper(II) give highly enantioselective vinylogous Mukaiyama-type aldol reactions under mild conditions.137 A chiral sulfinyl group has been used to achieve 1,5- and 1,6-asymmetric induction in Mukaiyama aldols, using Yb(OTf)3 catalysis.138... 

The third part of this chapter reviews previously described catalytic asymmetric reactions that can be promoted by chiral lanthanoid complexes. Transformations such as Diels-Alder reactions, Mukaiyama aldol reactions, several types of reductions, Michael addition reactions, hydrosilylations, and hydroaminations proceed under asymmetric catalysis in the presence of chiral lanthanoid complexes. 

As discussed in Section III J, in general, catalytic asymmetric aldol reactions have been studied using enol silyl ethers, enol methyl ethers, or ketene silyl acetals as a starting material. So far several types of chiral catalysis have been reported.75-85 The chiral lanthanoid complex prepared from Ln(OTf)3 and a chiral sulfonamide ligand was effective in promoting an asymmetric Mukaiyama aldol reaction with a ketene silyl acetal.86 The preparation of the catalyst and a representative reaction are shown in Figure 45. 

Besides the Mukaiyama aldol and the carbonyl-ene reactions another successful application of asymmetric catalysis is the nitro-aldol reaction... 

Keck also investigated asymmetric catalysis with a BINOL-derived titanium complex [102,103] for the Mukaiyama aldol reaction. The reaction of a-benzyloxyalde-hyde with Danishefsky s dienes as functionalized silyl enol ethers gave aldol products instead of hetero Diels-Alder cycloadducts (Sch. 40) [103], The aldol product can be transformed into hetero Diels-Alder type adducts by acid-catalyzed cyclization. The catalyst was prepared from BINOL and Ti(OPr )4, in 1 1 or 2 1 stoichiometry, and oven-dried MS 4A, in ether under reflux. They reported the catalyst to be of BINOL-Ti(OPr% structure. 

The same group of workers has proceeded to develop an intramolecular version of the reaction. The aldehyde acids (35, n = 1 or 2) on treatment with Mukaiyama s reagent, 2-chloro-l-methylpyridinium iodide, and triethylamine afforded the cis substituted bicyclic lactones (36, n = 1 or 2). The authors have adduced evidence in support of a nucleophile-catalysed aldol lactonisation (NCAL) reaction mechanism rather than the alternative thermal [2+2] cycloaddition. They have also found that the intramolecular reaction, like the intermolecular process, is subject to asymmetric catalysis. When an optically active base such as 0-acetylquinidine was present in the reaction mixture, the bicyclic lactones were produced with high ee <01 JA7945>. 

The Mukaiyama aldol reaction has also been used in the enantioselective asymmetric synthesis of 5-hydroxy-P-keto ester derivatives. Katsuki and coworkers utilized the chiral Cr(salen) complex 69 for the catalysis of the aldol reaction in the presence of water or alcohol. The presence of alcohol in the reaction greatly increases the enantioselectivity of the aldol addition. In the reaction of the silyl enol ether 92 with the aldehyde 93 in the presence of the catalyst 69, triethylamine, and isopropanol yielded the aldol adduct 94 in high yield (87%) and excellent enantioselectivity (97% ee). 

The asymmetric catalysis using SiCU and (107) is effective also in enantioselective Mukaiyama aldol reaction of TMS enolates derived from methyl ketones [164]. Addition of i-Pr2NEt improves the yield of adducts. The amine probably acts as a proton scavenger to suppress the protodesilylation of the enolates with adventitious HCl. The reaction of TMS enolates derived from ethyl ketones shows high anti diastereoselectivity as in the case of the TBS enolate of t-butyl propanoate. 

Catalysis with Bisoxazoline Complexes of Sn(II) and Cu(II). The bisoxazoline Cu(IT) and Sn(II) complexes 81-85 that have proven successful in the acetate additions with aldehydes 86,87, 88 also function as catalysts for the corresponding asymmetric propionate Mukaiyama aldol addition reactions (Scheme 8B2.8) [27]. It is worth noting that eithersyn or anti simple diastereoselectivity may be obtained by appropriate selection of either Sn(II) or Cu(II) complexes (Table 8B2.12). 

Novel C-C coupling reactions are about to enter the scope of metal complex catalysis. Examples are asymmetric aldolizations (Mukaiyama [79]), Diels-Alder reactions [80], and indium- or zinc-mediated alkylations [86]. 

During the last decade, use of oxazaborolidines and dioxaborolidines in enantioselective catalysis has gained importance. [1, 2] One of the earliest examples of oxazaborolidines as an enantioselective catalyst in the reduction of ketones/ketoxime ethers to secondary alco-hols/amines was reported by Itsuno et al. [3] in which (5 )-valinol was used as a chiral ligand. Since then, a number of other oxazaborolidines and dioxaborolidines have been investigated as enantioselective catalysts in a number of organic transformations viz a) reduction of ketones to alcohols, b) addition of dialkyl zinc to aldehydes, c) asymmetric allylation of aldehydes, d) Diels-Alder cycloaddition reactions, e) Mukaiyama Michael type of aldol condensations, f) cyclopropana-tion reaction of olefins. 

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