Lewis acid-catalyzed Michael addition

Lewis acid-catalyzed Michael addition of silyl enol ether to a,P-unsaturated system. 

Some of the Lewis acid catalyzed Michael additions to a,3-unsaturated carbonyls can also be rationalized based on these models. For example, BFs-mediated additions of organocopper reagents to chiral a,3-unsaturated esters such as (-)-8-phenylmenthyl crotonate (35) occur with high levels of dia-stereoselectivity. " The product stereochemistries for these reactions could be predicted by assuming the reactive conformation (35S), which follows the basic structural tenets of model A (Figure 41). ... 

Enamine and Lewis-acid-catalyzed Michael additions provide a useful complement to the enolate Michael addition. These variants allow for the reaction to be carried out under nearly neutral or formally acidic conditions. In terms of the stereochemistry, the enolate Michael addition appears at this point to be more versatile in that both stereoisomers are often obtainable from a given set of substrates. However, in particular cases, the enamine or the... 

In this synthesis of 1,5-dicaibonyl compounds, 3-butenyl halide is behaving as a masked 3-oxobutyl reagent, and can be used as an equivalent of meAyl vinyl ketone. These reactions offer new anellation mediods. Also 1,4-addition of the allyl group to enones, followed by oxidation, offers a convenient synthetic method for 1,5-diketone preparation. Lewis acid promoted Michael addition of allylsilane (48) to a, -unsaturated ketones, followed by the palladium-catalyzed oxidation, affords 1,5-diketones (Scheme 17)."3... 

The Lewis acid-catalyzed conjugate addition of silyl enol ethers to a,y3-unsaturated carbonyl derivatives, the Mukaiyaraa Michael reaction, is known to be a mild, versatile method for carbon-cabon bond formation. Although the development of catalytic asymmetric variants of this process provides access to optically active 1,5-dicarbonyl synthons, few such applications have yet been reported [108], Mukiyama demonstrated asymmetric catalysis with BINOL-Ti oxide prepared from (/-Pr0)2Ti=0 and BINOL and obtained a 1,4-adduct in high % ee (Sch. 43) [109]. The enantioselectiv-ity was highly dependent on the ester substituent of the silyl enol ether employed. Thus the reaction of cyclopentenone with the sterically hindered silyl enol ether derived from 5-diphenylmethyl ethanethioate proceeds highly enantioselectively. Sco-lastico also reported that reactions promoted by TADDOL-derived titanium complexes gave the syn product exclusively, although with only moderate enantioselectiv-ity (Sch. 44) [110]. 

The second major modification was developed by Mukaiyama and coworkers (4) and Hosomi and Sakurai (5). These workers found that weakly nucleophilic silyl enol ethers and allylsilanes add to a,/ -unsaturated ketones that have been precomplexed with a Lewis acid. This process formally mimics the protic-acid-catalyzed Michael addition but allows for regiocontrol over enol generation. 

Protic-acid-catalyzed Michael additions (59) are subject to most of the limitations of base-catalyzed Michael additions (regioselectivity and stereoselectivity of enol generation, polyaddition, etc.), and hence, the stereochemistry has been little studied (60). At low temperatures silyl and stannyl enol ethers,+ ketene acetals, and allyl species are unreactive to all but the most reactive activated olefins. However, it was discovered by Mukaiyama and co-workers that enol ethers and ketene acetals react with a,/f-unsaturated carbonyl compounds in the presence of certain Lewis acids (4,61,62). Sakurai, Hosomi, and co-workers found that allylsilanes behave similarly (5,63,64). 

In 1974,Mukaiyama and co-workers reported the first examples of Lewis acid-catalyzed Michael reactions between silyl enolates and a,p-unsaturated carbonyl compounds [33]. Evans and co-workers developed a catalytic asymmetric Michael reaction of silyl enol ethers of thiol esters to alkylidene malonates. For example, the reaction of alkylidene malonate 23 with 2.2 equiv of silyl enol ether 22 was carried out in the presence of 10 mol % of catalyst 25 and 2 equiv of hexa-fluoro-2-propanol (HFIP) in PhMe/CH2Cl2 (3 1) at -78 °C to give the expected adduct 24 in 93% ee (Scheme 5) [34]. Borane complex-catalyzed asymmetric Michael addition has also been reported [35]. 

This reaction was first reported by Mukaiyama et al. in 1974. It is a Lewis acid-catalyzed Michael conjugate addition of silyl enol ether to o ,/3-unsaturated compounds. Therefore, it is generally referred to as the Mukaiyama-Michael reaction. Because this reaction is essentially a conjugate addition, it is also known as the Mukaiyama-Michael addition or Mukaiyama-Michael conjugate addition. This reaction is a mechanistic complement for the base-catalyzed Michael addition, j and often occurs at much milder conditions and affords superior regioselectivity. s Besides silyl enol ether, silyl ketene acetals are also suitable nucleophiles in this reaction.For the hindered ketene silyl acetals, the Lewis acid actually mediates the electron transfer from the nucleophiles to o ,/3-unsaturated carbonyl molecules.On the other hand, the Q ,j8-unsaturated compounds, such as 3-crotonoyl-2-oxazolidinone, alkylidene malonates, and a-acyl-a,/3-unsaturated phosphonates are often applied as the Michael acceptors. It has been found that the enantioselectivity is very sensitive to the reactant structures —for example, Q -acyl-Q ,j8-unsaturated phosphonates especially prefers the unique syn- vs anft-diastereoselectivity in this reaction. In addition,... 

For example, using (/ )-5-trimethylsilyl-2-cyclohexenone as the chiral Michael acceptor, optically active m // .v-3.5-disubstituied cyclohexanones 1 are obtained via a Lewis acid catalyzed addition of silylenol ethers or ketene acetals. 

Nitroalkenes are also reactive Michael acceptors under Lewis acid-catalyzed conditions. Titanium tetrachloride or stannic tetrachloride can induce addition of silyl enol ethers. The initial adduct is trapped in a cyclic form by trimethylsilylation.316 Hydrolysis of this intermediate regenerates the carbonyl group and also converts the ad-nitro group to a carbonyl.317... 

Jenner investigated the kinetic pressure effect on some specific Michael and Henry reactions and found that the observed activation volumes of the Michael reaction between nitromethane and methyl vinyl ketone are largely dependent on the magnitude of the electrostriction effect, which is highest in the lanthanide-catalyzed reaction and lowest in the base-catalyzed version. In the latter case, the reverse reaction is insensitive to pressure.52 Recently, Kobayashi and co-workers reported a highly efficient Lewis-acid-catalyzed asymmetric Michael addition in water.53 A variety of unsaturated carbonyl derivatives gave selective Michael additions with a-nitrocycloalkanones in water, at room temperature without any added catalyst or in a very dilute aqueous solution of potassium carbonate (Eq. 10.24).54... 

Furthermore, a neighboring group participation of a phenylthio function is observed in the Lewis acid-catalyzed nucleophilic substitution reaction of various P-nitrosulfides. Because the P-nitrosulfides are readily available, by the Michael addition of thiols to nitroalkenes (see Michael addition Chapter 4), this reaction is very useful. The P-nitrosulfides are prepared stereoselectively, and the reaction proceeds in a stereo-specific way (retention of configuration) as shown in Eqs. 31-34.35... 

It has been shown that Lewis acid catalyzed isomerization of thionolactones provides access to thiolactones. For example, exposure of the substrate 22 to catalytic amounts of BF3 OEt2 led to efficient conversion to the thiolactone 23. Such transformations were also found to give minor amounts of lactone or dithiolactone side products <06TL6067>. Substituted tetrahydrothiophene derivatives have also been obtained from 1,4-dithiane-2,5-diol and 2-nitroethyl acetate derivatives by a base induced sequence featuring a Michael addition and a Henry reaction <06TL8087>. 

Lewis acid catalyzed reaction of oximes 172 (equation 113) with divinyl ketone (173) provided l-aza-7-oxabicyclo[3.2.1]octan-4-ones 174 through a sequential Michael addition and [3 + 2] cycloaddition. The reaction occurred with complete stereoselectivity giving the same product with both cis- and frawi-oximes . 

Several examples have been described on Lewis acid and base catalyzed Michael additions. Cyclopentanone-2-carboxylic acid ethylester was added at room temperature to methyl vinyl ketone using 2 mol% FeCl3 -6 H20 as catalyst yielding > 90% of the addition product (Scheme 11) [31]. Cerium(III) chloride in the presence of sodium iodide [32] and trifluoro-methanesulfonic acid have been used as catalysts as well [33]. 

An efficient asymmetric synthesis of the 3-substituted /3-sultams 163 has been reported. The key step of the synthesis is the Lewis acid-catalyzed aza-Michael addition of the enantiopure hydrazines (A)-l-amino-2-methoxy-methylpyrrolidine (SAMP) or CR,l ,l )-2-amino-3-methoxymethyl-2-azabicyclo[3.3.0]octane (RAMBO) to the alke-nylsulfonyl sulfonates 176. /3-Hydrazino sulfonates were obtained in good yield and excellent enantioselectivity. Cleavage of the sulfonates followed by chlorination resulted in the corresponding sulfonyl chlorides 177. The (A)-3-substituted /3-sultams 163 have been obtained in moderate to good yields and high enantioselectivity over two steps, an acidic N-deprotection followed by in situ cyclization promoted by triethylamine (Scheme 55) <2002TL5109, 2003S1856>. 

Molecular iodine-promoted Michael addition is a simple and efficient method for generating 2-pyrrolyl-2-phenyl-l-nitroalkanes in good yields (Scheme 67) [86]. Cr+3-Catsan (Cr+3 exchanged commercially available montmorillonite clay) and ZnCl2, which were first used as Lewis acids for Michael reactions of pyrrole, showed different selectivity under the same conditions [221], In general, while the reactions catalyzed by Cr+3-Catsan... 

A number of selective transformations (Fig. 10) have been described which include the selective allylation on alcohols in the presence of amides [47], the Lewis acid catalyzed cleavage of benzyl alcohol esters with secondary amines to afford tertiary amides [48], the synthesis of ketones from Weinreb-type amides [49], and the synthesis of tertiary amines by a Michael addition/alkylation/Hoffman elimination sequence [50],... 

Lewis acid-catalyzed tandem Michael imino-aldol reactions enable the one-pot synthesis of 7-acyl-(5-lactams from a, j6-unsaturated thio-esters, silyl enolates and imines [15]. For the initial Michael addition, the combination of SbClj with Sn(OTf>3 (5 mol %) proved to be efficient. However, after the addition of the imino compound the iminoaldol product was isolated in moderate yield. For the enhancement of turnover and yield, Sc(OTf)3, once again proved to be the Lewis acid of choice (Scheme 4, 15 16 = 81 19, 94%). 

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