Mukaiyama-type Michael reaction

Michael Reactions. Several reports highlighting utilization of the title reagent in Mukaiyama-type Michael reactions have now appeared. 3,4-Dihydro-Q -pyrones are obtained in quantitative yield from the reagent and a, -unsaturated ketones via a two-step sequence comprising conjugate addition followed by mercuric ion mediated cycUzation (eq 11). ... 

Kitazume and coworkers used microreactors with microchaimels 100 pm wide and 40 pm deep for the synthesis of a series of organofluorine compounds [19,20]. The silylation of4,4,4-trifluorobutan-2-one and the Mukaiyama-type aldol reaction of the resulting enol silyl ether with acetals gave good yields of the desired products [20]. They also described nitro-aldol reactions of 2,2-difluoro-l-ethoxyethanol and Michael additions of nitroalkanes to ethyl 4,4,4-trifluorocrotonate and ethyl 4,4-difluorocrotonate [19,20]. Reactions were carried out at room temperature, and... 

A possible mechanism for the catalytic [2+2] cycloaddition reaction catalyzed by Tf2NH is depicted in Scheme 4.9. The Mukaiyama-type Michael addition of silyl enol ether to enoate catalyzed by silyl triflic imide aHbrds the corresponding silyl ketene acetal, and then it proceeds successively to the intramolecular silyl oxonium carbon to... 

By 1989 Mukaiyama had already explored the behaviour of phosphonium salts as Lewis acid catalysts. It was possible to show that the aldol-type reaction of aldehydes or acetals with several nucleophiles and the Michael reaction of a,j3-unsatu-rated ketones or acetals with silyl nucleophiles gave the products in good yields with a phosphonium salt catalyst [116]. In addition, the same group applied bisphosphonium salts as shown in Scheme 45 in the synthesis of ]3-aminoesters [117]. High yields up to 98% were obtained in the reaction of A-benzylideneaniline and the ketene silyl acetal of methyl isobutyrate. Various analogues of the reaction parteers gave similar results. The bisphosphonium salt was found to be superior to Lewis acids like TiCl and SnCl, which are deactivated by the resulting amines. 

Intermolecular Michael addition [4.1] Intermolecular aldol reaction [6.2.1] Intramolecular aldol reaction [6.2.2] Aldol-related reactions (e.g. vinylogous Mukaiyama-type aldol) [6.2.3]... 

The chiral acyloxyborane 7 (CAB) has also been found to be an excellent catalyst for asymmetric Mukaiyama-Michael type aldol reaction between silyl enol ethers and aldehydes (Scheme 8). Yamamoto et al. [27] have used 20 mol % of CAB in propionitrile at -78 °C as a highly efficient catalyst for the condensation of several E and Z silyl enol ethers and ketene acetals with a variety of aldehydes (yields 49-97 %, 80-97 % ee). 

After pioneering work on the Lewis base-catalysed Mukaiyama aldol reaction, Mukaiyama-Michael reaction, and Mukaiyama-Mannich-type reaction with the use of lithium acetate, Mukaiyama also demonstrated the same reactions using simple sodium salts (Scheme 2.28). For example, a catalytic Mukaiyama aldol reaction between benzaldehyde and trimethylsilyl enolate using sodium methoxide in DMF proceeded smoothly under mild conditions. Moreover, the Mukaiyama-Michael reaction between chalcone and trimethylsilyl enolates using sodium acetate in DMF provided the desired Michael adduct as the major product in 92% yield along with the 1,2-adduct in 8% yield. ... 

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). 

While several resin- or polymer-supported Sc(OTf)3 catalysts have been developed and some of them are commercially available, a drawback of these catalysts is that their catalytic ability and reusability are still not satisfactory. Conceptually new methods, polymer incarcerated (PI) method and polymer-micelle incarcerated (PMI) have been developed to immobilize Sc(OTf)3 [100]. PMI Sc(OTf)3 is highly effective in several fundamental carbon-carbon bond-forming reactions, including Mukaiyama aldol, Mannich-type and Michael reactions. It is noted that the high catalytic activity in terms of TON (>7500) has been attained in Michael reaction. The catalyst was recovered quantitatively by simple filtration and reused several times without loss of catalytic activity, and no Sc leaching was observed in all the reactions (<0.1 ppm). 

Quite recently, cross-linked dendrimer was also found to be a good support for Sc(III) catalyst [101]. The resultant material could be used in water as a catalyst for three-component Mannich-type reactions and Mukaiyama aldol reactions. A simple immobilization method of Sc species by using montmorillonite as a support has also been reported recently [102]. This method provides a highly active heterogeneous catalyst for Michael reactions under aqueous or solvent-free conditions. 

Kobayashi and coworkers further developed a new immobilizing technique for metal catalysts, a PI method [58-61]. They originally used the technique for palladium catalysts, and then applied it to Lewis acids. The PI method was successfully used for the preparation of immobilized Sc(OTf)3. When copolymer (122) was used for the microencapsulation of Sc(OTf)3, remarkable solvent effects were observed. Random aggregation of copolymer (122)-Sc(OTf)3 was obtained in toluene, which was named as polymer incarcerated (PI) Sc(OTf)3. On the other hand, spherical micelles were formed in THF-cyclohexane, which was named polymer-micelle incarcerated (PMI) Sc(OTf)3.. PMI Sc(OTf)3 worked well in the Mukaiyama-aldol reaction of benzaldehyde with (123) and showed higher catalytic activity compared to that of PI Sc(OTf)3 mainly due to its larger surface area of PMI Sc(OTf)3. This catalyst was also used in other reactions such as Mannich-type (123) and (125) and Michael (127) and (128) reactions. For Michael reactions, inorganic support such as montmorilonite-enwrapped Scandium is also an efficient catalyst [62]. 

SCHEME 59 Effects of amine-type organocatalysts in the vinylogous Mukaiyama-Michael reaction. 

The elfectiveness of imidazolidinone of type 11 was confirmed by successful application to a broad range of chemical transformations, including cycloadditions, conjugate additions, Friedel-Crafts alkylations, Mukaiyama-Michael additions, hydrogenations, cyclopropanations, and epoxidations. A summary of these enantio-selective iminium catalyzed processes is provided by reaction subclass. 

During the past decades, the scope of Lewis acid catalysts was expanded with several organic salts. The adjustment of optimal counter anion is of significant importance, while it predetermines the nature and intensity of catalytic Lewis acid activation of the reactive species. Discovered over 100 years ago and diversely spectroscopically and computationally investigated [131-133], carbocations stiU remain seldom represented in organocatalysis, contrary to analogous of silyl salts for example. The first reported application of a carbenium salt introduced the trityl perchlorate 51 (Scheme 49) as a catalyst in the Mukaiyama aldol-type reactions and Michael transformations (Scheme 50) [134-142]. 

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. 

Three-component coupling reaction of a-enones, silyl enolates, and aldehydes by successive Mukaiyama-Michael and aldol reactions is a powerful method for stereoselective construction of highly functionahzed molecules valuable as synthetic intermediates of natural compounds [231c]. Kobayashi et al. recently reported the synthesis of y-acyl-d-lactams from ketene silyl thioacetals, a,/l-urisalu-rated thioesters, and imines via successive SbCl5-Sn(OTf)2-catalyzed Mukaiyama-Michael and Sc(OTf)3-catalyzed Mannich-type reactions (Scheme 10.87) [241]. 

The titanium(IV) chloride-promoted reactions of enol silyl ethers with aldehydes, ketones, and acetals, known as Mukaiyama reaction, are useful as aldol type reactions which proceed under acidic conditions (eq (23)) [20], Enol silyl ethers also undergo the Michael type reactions with enones or p.y-unsaturated acetals (eq (24)) [21]. Under similar reaction conditions, enol silyl ethers are alkylated with reactive alkyl halides such as tertiary halides or chloromethyl sulfides (eq (25)) [22], and acylated with acid halides to give 1,3-diketones (eq (26)) [23]. 

BiCl.i and BiCl,-metal iodide catalyzed Mukaiyama-aldol and Michael-type reactions... 

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. 

The conditions used for the Mukaiyama-aldol type reactions employing InCh (see Section 8.2) were found by Loh et al. to be useful in Michael-type additions of silyl enol ethers to a,P-unsaturated carbonyl compounds [49] (Figure 8.25). 

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