Michael reaction complex

The enantioselective 1,4-addition addition of organometaUic reagents to a,p-unsaturated carbonyl compounds, the so-called Michael reaction, provides a powerful method for the synthesis of optically active compounds by carbon-carbon bond formation [129]. Therefore, symmetrical and unsymmetrical MiniPHOS phosphines were used for in situ preparation of copper-catalysts, and employed in an optimization study on Cu(I)-catalyzed Michael reactions of di-ethylzinc to a, -unsaturated ketones (Scheme 31) [29,30]. In most cases, complete conversion and good enantioselectivity were obtained and no 1,2-addition product was detected, showing complete regioselectivity. Of interest, the enantioselectivity observed using Cu(I) directly in place of Cu(II) allowed enhanced enantioselectivity, implying that the chiral environment of the Cu(I) complex produced by in situ reduction of Cu(II) may be less selective than the one with preformed Cu(I). 

Heterobimetallic asymmetric complexes contain both Bronsted basic and Lewis acidic functionalities. These complexes have been developed by Shibasaki and coworkers and have proved to be highly efficient catalysts for many types of asymmetric reactions, including catalytic asymmetric nitro-aldol reaction (see Section 3.3) and Michael reaction. They have reported that the multifunctional catalyst (f )-LPB [LaK3tris(f )-binaphthoxide] controls the Michael addition of nitromethane to chalcones with >95% ee (Eq. 4.140).205... 

In the very recent past, metal complex catalysis has been used with advantage for the stereo- and enantio selective syntheses based on the Henry and Michael reactions with SENAs (454-458). The characteristic features of these transformations can be exemplified by catalysis of the reactions of SENAs (327) with functionalized imides (328) by ligated trivalent scandium complexes or mono-and divalent copper complexes (454) (Scheme 3.192). Apparently, the catalyst initially forms a complex with imide (328), which reacts with nitronate (327) to give the key intermediate A. Evidently, diastereo- and enantioselectivity of the process are associated with preferable transformations of this intermediate. 

Table 6. Catalytic asymmetric Michael reactions promoted by the AlMbis(R)-binaphthoxide) complex (AMB).

Moreover, these rare earth heterobimetallic complexes can be utilized for a variety of efficient catalytic asymmetric reactions as shown in Scheme 7 Next we began with the development of an amphoteric asymmetric catalyst assembled from aluminum and an alkali metal.1171 The new asymmetric catalyst could be prepared efficiently from LiAlH4 and 2 mol equiv of (R)-BINOL, and the structure was unequivocally determined by X-ray crystallographic analysis (Scheme 8). This aluminum-lithium-BINOL complex (ALB) was highly effective in the Michael reaction of cyclohexenone 75 with dibenzyl malonate 77, giving 82 with 99% ee and 88 % yield at room temperature. Although LLB and... 

The reactivity of phenylacetic esters with electron-deficient alkenes is generally fairly poor, even under phase-transfer catalytic conditions. The reaction with cinnamic esters is often accompanied by hydrolysis and the yield of the adduct with chalcone is generally <60% [10]. The activity of the methylene group towards alkylation has been enhanced by the initial complexation of the phenyl ring with chromium tricarbonyl (see Section 6.2), but this procedure has not been applied to the Michael reaction. 

Asymmetric allylic C-H activation of more complex substrates reveals some intrinsic features of the Rh2(S-DOSP)4 donor/acceptor carbenoids [135, 136]. Cyclopropanation of trans-disubstituted or highly substituted alkenes is rarely observed, due to the steric demands of these carbenoids [16]. Therefore, the C-H activation pathway is inherently enhanced at substituted allylic sites and the bulky rhodium carbenoid discriminates between accessible secondary sites for diastereoselective C-H insertion. As a result, the asymmetric allylic C-H activation provides alternative methods for the preparation of chiral molecules traditionally derived from classic C-C bond-forming reactions such as the Michael reaction and the Claisen rearrangement [135, 136]. 

The more bulky 1-ethoxycyclopropyl group also induced a complete Z-diastereoselec-tivity to the Michael reaction of the ethynyl carbene complex with dimethylamine (equation 179)246. This is due to the sterically favored arm-position acquired by the bulky group in the intermediate. Unlike the parent cyclopropyl carbene complex, which gave only... 

MB) by the base can result in dye loss. Addition of the activator to the monomer in a Michael reaction, particularly critical for the sulfinate activators (43), can lead to loss of activator. A third, less well-characterized process, can also occur in addition to these two dominant deactivation processes. The interaction of some activators, for example, phosphines (19) and amines, with certain dyes result in the formation of complexes (80-83). The complexes generally absorb at shorter wavelengths than the dye, and can complicate the system photochemistry as well as induce deleterious ground state chemistry. 

Chiral metal alkoxides and naphthoxides have been used as catalysts for asymmetric Michael reaction. An early successful example was reported by Cram et al., who used 4 mol % of KO Bu-chiral crown ether 8 complex as the catalyst to afford the Michael adduct with up to 99% ee (Scheme 8D.7) [16], In this case KO Bu complexed with chiral crown ether 8 plays two... 

Complex LSB 9 is readily prepared either by the reaction of La(0 Pr)3 with 3 equiv. of B1NOL followed by the addition of NaO Bu (3 equiv.) or by the reaction of LaCl nfLO with sodium binaphthoxide. The complex 9 is stable to oxygen and moisture and has been proven to be effective in the catalytic Michael reaction of various enones with either malonates or p-keto esters. The Michael adducts with up to 92% ee were obtained in almost quantitative yield. Typical results with malonates are summarized in Table 8D.1 (Ln = lanthanide) [18], In general, the use of THF as solvent gave the best results except for the case of the LSB-catalyzed reaction of rmns-chalcone with dimethyl malonate, wherein the use of toluene was essential to give the adduct with good enantiomeric excess. The effects of the central metal (La, Pr, and Gd) on asymmetric induction were also examined in the same reaction, and LSB was found to be the best catalyst. 

Another highly useful heterobimetallic catalyst is the aluminum-lithium-BINOL complex (ALB) prepared from LiAlH4 and 2 equiv. of (/ )-BINOL. The ALB catalyst (10 mol %) is also effective in the Michael reaction of enones with various malonates, giving Michael products generally with excellent enantioselectivity (91-99% ee) and in excellent yields [23]. These results ate summarized in Table 8D.3. Although LLB and LSB complement each other in their ability to catalyze asymmetric nitroaldol and Michael reactions, respectively, the Al-M-(/ )-BINOL complexes (M = Li, Na, K, and Ba) are commonly useful for the catalytic asymmetric Michael reaction. 

Third heterobimetallic asymmetric catalyst reported by Shibasaki et al., gallium-sodium-BINOL complex (GaSB) 26 and indium-potassium-BINOL complex (InPB), are also rather effective catalysts for asymmetric Michael reactions, and GaSB was better than InPB in terms of enantioselectivity. The GaSB catalyst was prepared from GaCl3, NaO Bu (4 mol equiv. to... 

The first investigations on iron-catalyzed Michael reactions utilized Fe(acac)3 as catalyst. However, this metal complex is itself catalytically almost inactive. Yields of only up to 63% could be achieved, if BF3OEt2 is used as a co-catalyst [55], Polystyrene-bound Fe(acac)3 catalysts were also reported to give yields up to 63% [56], FeCl3 was used as a co-catalyst for clay-supported Ni(II). Yields achieved with this heterogeneous system ranged from 40 to 98% [57]. The double Michael addition of acrylonitrile to ethyl cyanoacetate is smoothly catalyzed by a complex generated from [Fe(N2) (depe)2] [depe = l,2-bis(diethylphosphano)ethane]. At 23 °C and after 36h, an 88% yield is obtained with 1 mol% of this Fe(0) catalyst [58]. 

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