Mukaiyama aldol reactions applications

Eor the application of C2-symmetric bis-oxazoline-Lewis acids in other catalytic reactions (a) Mukaiyama-aldol reactions see, e.g., D.A. Evans, M.C. Kozlowski,... 

Herein we will focus on the recent development of vinylogous [1] aldol reactions and their application in the synthesis of natural products [2-5]. In particular the synthesis of unsaturated esters through the vinylogous Mukaiyama aldol reaction is of great interest, since it provides rapid access to larger carbon frameworks and allows for a wide variety of transformations of the double bond (dihydroxylation, epoxidation, cuprate addition etc.). 

To start with the addition of y-dienolates to aldehydes, the so-called vinylogous Mukaiyama aldol reaction, Campagne et al. studied the applicability of different types of catalyst when using the silyldienolate 115 as nucleophile [121]. In general, many products obtained by means of this type of reaction are of interest in the total synthesis of natural products. It should be added that use of CuF-(S)-TolBinap (10 mol%) as metal-based catalyst led to 68% yield and enantioselectivity up to... 

As one of the first groups, Reetz et al. [6] reported a catalytic Mukaiyama aldol reaction (Scheme 3a) with the chiral aluminum complex 13. However, low yields and a low level of enan-tioselectivity made this reaction not generally applicable. 

Miscellaneous. There are several other reports on the application of this ligand to catalytic asymmetric reactions, although enantioselectivities are modest. Those reports include the Mukaiyama-Michael reaction, allylation of aldehydes, asymmetric Diels-Alder reaction, Mukaiyama-Aldol reaction of ketomalonate, aziridination reaction of a-imino esters, and asymmetric hetero-Diels-Alder reaction. ... 

Aldol-type condensation of silyl enol ethers with acetals under the influence of la is rather familiar. Unlike the Mukaiyama aldol reaction, 1-5 mol % loading of la is enough to complete the coupling reaction under mild conditions [20]. This transformation is applicable to the synthesis of a wide variety of / -alkoxy carbonyl substrates and has three characteristic features ... 

The directed aldol reaction is an important means of selective carbon-carbon bond formation. This reaction is efficiently achieved by the transformation of one carbonyl group to a silylated enol derivative, which subsequently couples with another carbonyl compound with the aid of a Lewis acid, typically TiCl4, as formulated in Eq. (2). This type of directed aldol reaction is called the Mukaiyama aldol reaction, a standard and practical synthetic protocol with broad application which has, accordingly, been reviewed extensively [38-42] in addition to the reviews cited in the introductory section. The fundamental reactions between enol silyl ethers and an aldehyde or a ketone... 

The directed aldol reaction in the presence of TiC found many applications in natural product synthesis. Equation (7) shows an example of the aldol reaction utilized in the synthesis of tautomycin [46], in which many sensitive functional groups survived the reaction conditions. The production of the depicted single isomer after the titanium-mediated aldol reaction could be rationalized in terms of the chelation-controlled (anft-Felkin) reaction path [37]. A stereochemical model has been presented for merged 1,2- and 1,3-asymmetric induction in diastereoselective Mukaiyama aldol reaction and related processes [47]. 

Fig. 30 OS supported box ligand application to Diels Alder and Mukaiyama aldol reactions...

The Lewis acidic nature of these catalysts has permitted their extended use in the Mukaiyama aldol reaction. In this application of CBS reagents, one such example involved the condensation of ketene acetals 72 with aldehydes 73 to produce adducts 74.20... 

The role of the ligand has been found to be crucial in the silyl Lewis acid Mukaiyama aldol reaction, which opens interesting applications for synthetic organic chemistry. When TMSOTf induces the reaction, the silyl group of TMSOTf remains in the product and that of the silyl enol ether becomes the catalyst for the next catalytic cycle however, if the reaction is promoted by TMSNTf2, the silyl group of the catalyst is not released from... 

Chiral Catalysts Containing Group 11 Metals (Cu, Ag, and Au). The most recent publications on the chiral copper catalysts are mainly dealing with those containing bis(oxazoline)-type ligands (Fig. 22). Cationic [Cu( Bu-BOX)] + complexes with OTf , [SbFe] , counterions catalyze Michael reactions, and various types of cycloadditions (292). Copper(II)-PYBOX complexes have been shown to catalyze enantioselective Mukaiyama aldol reactions (293). Similarly, bisoxa-zoline derivatives serve as ligands in the catalytic system prepared in situ from Cud) salts and are used for asymmetric peroxidation and enantioselective Meer-wein arylation of activated olefins (294). The copper-BOX-triflate complexes have found wide applications in cyclopropanation of alkenes (60), furans (295), and aziridination of alkenes (296). 

Conventional organic solvents have also been used. Mukaiyama aldol reaction of methyl 3-(trialkylsilanyloxy)-2-diazo-3-butenoate proceeded very well in dichloromethane using Sc(OTf)3 (Scheme 12.2) [4]. No decomposition of the diazo moiety was observed in this system and Sc(OTf)3 was applicable to Mannich reactions of the same substrate. 

Aldol Reactions. The title reagent and its various congeners continue to find application in Mukaiyama-t3fpe aldol reactions as versatile nucleophilic propionate synthons with predictable behavior.For example, the ( )-isomer of the reagent produced the expected major isomer in a boron trifiuoride etherate mediated addition to a complex aldehyde en route to a C19-C35 subunit of swinholide A (eq 14). Remote stereoinduction in Mukaiyama aldol reactions of the reagent with (2-sulfinylphenyl)acetaldehydes was recently observed anti aldol adducts were obtained preferentially regardless of the geometry of the silyl ketene thioacetal employed. ... 

Although aminocatalysis of the aldol reaction via enamine intermediates is an important enzymatic strategy and several bioorganic studies of the subject have appeared, applications in preparative organic synthesis, particularly in intermolecular aldol addition reactions, have been published only sporadically. Despite the often-used Mukaiyama-aldol reaction of enol ethers and Stork s vell-developed enamine chemistry [37, 38], aldolizations of preformed enamines are rare. One report describes Le vis acid-catalyzed aldolizations of preformed enamines vith aldehydes that furnish aldol addition products [39]. Aldol condensation reactions of preformed enamines vith aldehydes have also been described [40]. Only enamine-catalytic aldolizations, vhich are primary and secondary amine-catalyzed aldol reactions, vill be discussed in this chapter, ho vever. 

In 2003, Rawal reported the use of TADDOLs 177 as chiral H-bonding catalysts to facilitate highly enantioselec-tive hetero-Diels-Alder reactions between dienes 181 and different aldehydes 86 (Scheme 6.29A) [82], and also BINOL-based catalysts 178 were found to facilitate this reaction with excellent selectivities [83]. TADDOLs were also successfully used as organocatalysts for other asymmetric transformations like Mukaiyama aldol reactions, nitroso aldol reactions, or Strecker reactions to mention a few examples only [84]. In addition, also BINOL derivatives have been employed as efficient chiral H-bonding activators as exemplified in the Morita-Baylis-Hilhnan reaction of enone 184 with different carbaldehydes 86 [85]. The use of chiral squaramides for asymmetric reactions dates back to 2005 when Xie et al. first used camphor-derived squaric amino alcohols as ligands in borane reductions [86]. The first truly organocatalytic application was described by Rawal et al. in 2008 who found that minute amounts of the bifunctional cinchona alkaloid-based squaramide 180 are... 

As further applications of their concept of hydrogen bond catalysis , Rawal and CO workers demonstrated the use of hydrogen bonding catalysis in enantioselective vinylogons Mukaiyama aldol reactions in 2005 (Scheme 1.28) [30c]. The reaction of the silyldienol ether (23) and a range of reactive aldehydes proceeds regiospecifically... 

This system based on the catalysis of 28 was extended to the development of vinylogous and bis-vinylogous Mukaiyama aldol reactions, which displayed good to excellent enantioselectivity and broad applicability with respect to sUyl ketene acetals of higher vinylogy (Scheme 7.54) [82]. 

The Mukaiyama-aldol reaction of silyl enol ethers is one of the most important carbon-carbon bond-forming reactions in organic synthesis. Therefore, its application to catalytic asymmetric synthesis has been investigated in depth for the last decade (52-56). In an analogy to the F-C reaction of vinyl ether, if a catalytic asymmetric F-C reaction proceeds under Mukaiyama conditions to give additional reactive silyl enol hers, sequential reactions with electrophiles could provide further functionalized products (chiral syn or a fi-a,/8-dihydroxythioesters as a-... 

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