Carbonyl compounds Sakurai allylation reaction

At the end of his review [7] dealing with the acetalization of carbonyl compounds, Sakurai reported a previously unpublished observation. In the presence of catalytic amounts of iodotrimethylsilane and one equivalent of tetramethoxysilane 38, allyl-trimethylsilane 1 underwent smooth condensation with benzaldehyde 39, leading to adduct 41 in good yield. The silyl-modified Sakurai reaction was born (Scheme 13.15). 

As a result of the preliminary examples described in Sect. 3.1 and the quest for automation techniques in solution-phase synthesis, various examples of continuous flow processes appeared in the literature lately which utilized solid-phase-bound chemical catalysts. In a simple example, Yamamoto and coworkers studied the use of super Bronsted acids loaded on polystyrene beads 5 for use in a single-pass column system (Fig. 4) [30]. It was shown that these columns are suited for the acetylation of alcohols, acetalization of carbonyl compounds, Sakurai-Hosomi allylation reactions, and Mukaiyama aldol reactions. 

A variety of electrophilic catalysts promote the addition of allylic silanes to carbonyl compounds.86 The original catalysts included typical Lewis acids such as TiCl4 or BFj.87 This reaction is often referred to as the Sakurai reaction. 

Allyl- and vinylsilane chemistry was one of the first areas of reagent synthesis impacted by CM methodology. Allylsilanes are commonly employed in nucleophilic additions to carbonyl compounds, epoxides, and Michael acceptors (the Sakurai reaction) vinylsilanes are useful reagents for palladium-coupling reactions. As the ubiquitous application of CM to this substrate class has recently been described in several excellent reviews, this topic will not be discussed in detail, with the exception of the use of silane moieties to direct CM stereoselectivity (previously discussed in Section 11.06.3.2). 

At the same time, Sakurai and Hosomi [6] extended this reaction to a wide range of non-activated carbonyl compounds 6, using TiCl4 as Lewis acid (Scheme 13.2). The allylation occurred rapidly at room temperature and is applicable to both aldehydes and ketones. 

Substituted allylsilanes are subject to ene reaction with aldehydes and a,/3-unsaturated carbonyl compounds in the presence of a Lewis acid. The Et2AlCl-promoted reaction of /3-siloxymethyl-substituted allylsilane 27 with aldehydes gives more functionalized allylsilanes (Equation (37)).148 The use of TiCU instead of Et2AlCl leads to the Hosomi-Sakurai allylation. Catalytic enantioselective carbonyl-ene reactions of methallylsilanes have been achieved by using chiral Ti and A1 complexes.149,150... 

Hollis, T. K., Robinson, N. p., Whelan, J., Bosnich, B. Homogeneous catalysis. Use of the TiCp2(CF3S03)2] catalyst for the Sakurai reaction of allylic silanes with orthoesters, acetals, ketals and carbonyl compounds. Tetrahedron Lett. 1993, 34,4309-4312. 

Modified Sakurai reaction.3 The original reaction involved the TiCI4-catalyzed addition of allyllrimclhylsilanc to aldehydes and ketones or the acetals and kctals to form homoallylic alcohols or ethers (7,370-371). Marko et al. have extended this reaction to a synthesis of homoallylic ethers by a Lewis acid catalyzed reaction of allyl-trimcthylsilanc with a carbonyl compound and a trimethylsilyl ether. 

The allylation of a carbonyl compound, or equivalent thereof (aldehydes, ketones, acetals, ketals, enones, acid chlorides, epoxides, etc.), performed with an allylsilane 39 promoted by a Lewis acid (TiCl, SnCl, BF3-OEt2, AICI3, EtjAlCl, etc.) is known as Hosomi-Sakurai reaction (Scheme 12.11, Eq. 1) [68, 69]. This reaction was first described in 1976, allowing the synthesis of homoallylic alcohols 43 from aldehydes and ketones 40 [70]. A year later, the authors extended the method to ketals 41, which provide homoallylic ethers 44 (Scheme 12.11, Eq. 2) [71], and to a,p-unsaturated ketones 42 (Scheme 12.11, Eq. 3) [72]. 

Finally, Chen s work on the direct allylation of carbonyl compounds using benzyl alcohol in the multicomponent Sakurai reaction catalyzed by selective and green solid acids, such as sihcomolybdic acid (SMA-SiO ) [92] or perchloric acid (HClO -SiOj) [93], both supported on silica gel, should be mentioned. In some cases, the use of preformed acetals as substrates provided better results. These methods allowed the synthesis of a broad number of homoallylic ethers in moderate to high yields in a short reaction time. Significantly, catalyst loading of HClO -SiOj is only 2mol%. 

The Sakurai reaction can be defined as the allylation of a carbonyl compound, or equivalent thereof, performed with an allylsilane and promoted by a Lewis acid. 

In 1976, Akira Hosomi and Hideki Sakurai of Tohoku University in Sendai, Japan, published a letter entitled Syntheses of y,S-Unsaturated Alcohols From Allylsilanes And Carbonyl Compounds In The Presence of Titanium Tetrachloride"The letter describes the reaction depicted in equation 1, in which allyl silanes react with aldehydes or ketones to provide homoallylic alcohols. The following year, Hosomi and Sakurai extended their finding to ketals, which provide homoallylic ethers (eq. 2)," and to a,P-unsaturated ketones (eq. 3), in which case the addition occurs in a 1,4-fashion and becomes a valuable method to generate quaternary centers. 

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