Silyl ketene acetals Mukaiyama reactions

Nucleophilic additions to a,3-dialkoxy aldehydes via allyl silanes (eq 3) or silyl ketene acetals (Mukaiyama reaction) (eq 4) exhibit similarly high selectivities. a-Thio aldehydes also react under MgBr2-catalyzed Mukaiyama conditions with efficient stereocontrol (eq 5). ... 

The Mukaiyama aldol reaction refers to Lewis acid-catalyzed aldol addition reactions of silyl enol ethers, silyl ketene acetals, and similar enolate equivalents,48 Silyl enol ethers are not sufficiently nucleophilic to react directly with aldehydes or ketones. However, Lewis acids cause reaction to occur by coordination at the carbonyl oxygen, activating the carbonyl group to nucleophilic attack. 

Silyloxy)alkenes were first reported by Mukaiyama as the requisite latent enolate equivalent to react with aldehydes in the presence of Lewis acid activators. This process is now referred to as the Mukaiyama aldol reaction (Scheme 3-12). In the presence of Lewis acid, anti-aldol condensation products can be obtained in most cases via the reaction of aldehydes and silyl ketene acetals generated from propionates under kinetic control. 

Another chiral auxiliary for controlling the absolute stereochemistry in Mukaiyama aldol reactions of chiral silyl ketene acetals has been derived from TV-methyl ephedrine.18 This has been successfully applied to the enantioselec-tive synthesis of various natural products19 such as a-methyl-/ -hydroxy esters (ee 91-94%),18,20 a-methyl-/Miydroxy aldehydes (91% ee),21 a-hydrazino and a-amino acids (78-91% ee),22 a-methyl-d-oxoesters (72-75% ee),20b cis- and trans-l1-lactams (70-96% ee),23 and carbapenem antibiotics.24... 

The isomerization of an O-silyl ketene acetal to a C-silyl ester is catalyzed by a cationic zirconocene—alkoxide complex [92], This catalysis was observed as a side reaction in the zirconocene-catalyzed Mukaiyama aldol reactions and has not yet found synthetic use. The solvent-free bis(triflate) [Cp2Zr(OTf)2] also catalyzes the reaction in nitromethane (no reaction in dichloromethane), but in this case there may be competitive catalysis by TMSOTf (cf. the above discussion of the catalysis of the Mukaiyama aldol reaction) [91] (Scheme 8.51). 

The undefined mechanism of the aldol-type Mukaiyama and Sakurai allylation reactions arose the discussion and interest in mechanistic studies [143-145]. The proposed mechanism was proved to proceed through the catalytic activation of the aldehyde and its interaction with the silyl ketene acetal or allylsilane producing the intermediate. From that point the investigation is complicated with two possible pathways that lead either to the release of TMS triflate salt and its electrophihc attack on the trityl group in the intermediate or to the intramolecular transfer of the TMS group to the aldolate position resulting in the evolution of the trityl catalyst and the formation of the product (Scheme 51). On this divergence, series of experimental and spectroscopic studies were conducted. 

Aldol reactions of aldehydes with cycloakanones were performed in ionic liquids and catalyzed by FeCl3-6H20 [32]. Mukaiyama aldol reactions of silylenol ethers with aldehydes can be carried out in aqueous media however, among several Lewis acidic catalysts investigated, iron compounds were not the optimal ones [33], If silyl ketene acetals are applied as carbon nucleophiles in Mukaiyama aldol reactions, cationic Fe(II) complexes give good results. As catalysts, CpFe(CO)2Cl [34] and [CpFe(dppe) (acetone)] BF4 [35] [dppe = l,2-bis(diphenylphosphano)ethane] were applied (Scheme 8.8). No diastereomeric ratio was reported for product 26a. 

Scheme 8.8 Mukaiyama aldol reactions of silyl ketene acetals with aldehydes.

As above (eq 1), a major drawback of this reagent is the lack of a readily available enantiomer. There are many alternative methods for the enantioselective propionate aldol reaction. The most versatile chirally modified propionate enolates or equivalents are N-propionyl-2-oxazolidinones, a-siloxy ketones, boron enolates with chiral ligands, as well as tin enolates. Especially rewarding are new chiral Lewis acids for the asymmetric Mukaiyama reaction of 0-silyl ketene acetals. Most of these reactions afford s yw-aldols good methods for the anri-isomers have only become available recently. ... 

Azaborolyl complex (- -)-218 has been used in a stereoselective Mukaiyama aldol reaction as illustrated in Scheme 32 <2005JA15352>. Complex (- -)-218 reacts with electron rich aromatic aldehydes and silyl ketene acetals to generate adduct 220. X-ray structures indicate the stereochemistry is as illustrated. This stereochemistry is... 

Asymmetric Mukaiyama aldol reactions and reactions of silyl ketene acetals have been reported, " usually using chiral additives" although chiral auxiliaries... 

Conjugate additions. Cyclopentaneacetic esters are readily prepared by cyclization of -iodo-a,P-unsaturated esters. The Michael reaction of silyl ketene acetals with enones (and Mukaiyama aldol reaction) can be promoted by Sml,. " However, thermodynamic enolsilylation of carbonyl compounds under similar conditions is noted. 

Recently, Chen has synthesized and resolved chiral suberyl carbenium ions and utilized these as catalysts for enantioselective Mukaiyama aldol addition reactions (Eq. (8.22)) [34]. Thus the reaction of the ethyl acetate-derived silyl ketene acetal with benzaldehyde in the presence of 10-20 mol% of catalyst afforded the corresponding adduct in 50% ee. The enantioselectivity of the process proved sensitive to the nature of the cation, consistent with observations previously highlighted by Denmark in related studies [35]. Although at the current level of development the selectivities are modest, the study documents a novel class of metal-free Lewis acidic agents. 

In a landmark study of Mukaiyama aldol addition reactions, Heathcock proposed that the observed stereochemical outcome of the products in the Lewis acid-mediated addition of silyl ketene acetals to aldehydes was consistent with extended, open transition-state structures [38a, 38b]. This analysis has gained wide acceptance as a consequence of its predictive power. Alternative models involving cyclic, closed structures have also been postulated, in particular, the latter have been invoked with increasing regularity in the analyses of catalytic, enantioselective aldol addition reactions [7,30b,39a,39b. ... 

In a novel departure from the traditional approach to the asymmetric Mukaiyama aldol, Denmark has reported a Lewis base-catalyzed aldol addition reaction of enol trichlorosilanes and aldehydes. These unusual silyl ketene acetals are readily prepared by treatment of the tributylstannyl enolates 246 with SiC (Eq. 51). In the initial ground-breaking studies, the methyl acetate-derived trichlorosilyl ketene acetal 247 was shown to add rapidly to a broad range of aldehydes at -80 C to give adducts (89-99% yield, Eq. 52). 

Acetate-derived silyl ketene acetals (11, 13 and 14) react with aldehydes with good stereoselectivity (equation 10) significant results are reported in Table 5. Removal of the auxiliary, with methanolic KOH, gave the corresponding (3-hydroxy acids in good enantiomeric excess (ee). The asymmetric variants of the Mukaiyama reaction also helped to solve the long-standing problem of an efficient anti selec-... 

The use of chiral Lewis acids for enantioselective Diels-Alder and hetero Diels-Alder reactions and for other processes of C—C bond formation has recently received great attention. Reetz and coworkers reported that a stoichiometric amount of the chiral Lewis acid (137) effectively promotes the reaction of silyl ketene acetal (98) to give the aldol product in 57% yield and 90% ee (equation 48, R = Me2CHCH2—). When a catalytic amount (5 mol %) of the chiral rhodium perchlorate (138) is used, the aldol product is obtained in >75% yield and 12% ee (equation 48 R = Ph). ° Both reactions probably proceed through the corresponding metal enolates. - The development of new efficient chiral catalysts for the Mukaiyama reaction is certainly one of the challenges of the 1990s. 

Mukaiyama-Michael reactions.4 This reaction involves addition of silyl ketenc acetals to cnones in the presence of a Lewis acid to form 1,5-keto esters (13,306-307 15,15). Surprisingly, a fi, /3-disubstituted enonc (1) in the presence of various Lewis acid catalysts reacts more rapidly with the disubstituted silyl ketenc acetal 2a than with the unhindered silyl ketene acetal 2b, to form the hindered adduct 3 with two adjacent quaternary carbon atoms. Similar results obtain with Bu2Sn(OTf)2 and TiCl4. The result is hardly consistent with a nucleophilic reaction, but suggests that the reaction involves... 

Another interesting example of the influence of high pressure on the regioselec-tivity in organic reactions has been observed for the Mukaiyama aldol reaction of unsaturated silyl ketene acetals (51) with aromatic aldehydes by Bellassoued, Dumas and coworkers (Scheme 8.14) [33]. The desired y-adduct 52 was the major compound up to 0.5 GPa (52 53 = 83 17) while the preference was reversed at 1.7 GPa, making the a-adduct 53 the predominant product (52 53 = 25 75). This pressure dependence of the regioselectivity may imply that the transition structure leading to the linear aldol product 52 is less compact than that in the formation of the branched aldol product 53. 

Mukaiyama-Michael addition. The reaction of silyl ketene acetals with enones is catalyzed with a species formed from P4O10 and MeCN. 

Catalyzed Mukaiyama-type aldol reactions of silyl enol ethers or silyl ketene acetals with aldehydes lead to the same products. For recent advances see a) G. E. Keck, D. Krishnamurthy, J. Am. Chem. Soc. 1995, 117, 2363 b) M. Sato, S. Sunami, Y. Sugita, C. Kaneko, Heterocycles 1995, 41, 1435, and references therein. 

When applied to the Mukaiyama reaction, the principles of stereodifferentiation can lead to excellent dias-tereoselection and enantioselection. When silyl ketene acetal 465 was reacted with chiral aldehyde 466 in the presence of TiCl4, a 75% yield of 467 and 468 was obtained as a 98 2 mixture, favoring 467. ... 

Pd(OAc)2, combined with DPPE, catalyzes aldol condensation of aldehydes or ketones with ketene silyl acetal (Mukaiyama reaction) under neutral conditions. The ketene silyl acetal of methyl isobutyrate (10) reacted smoothly with methyl pymvate (9) or benzaldehyde (12) in THF or MeCN using 0.1 % of the catalyst. In this reaction the Pd enolate 14 is generated by transmetallation of the ketene silyl acetal with Pd(OAc)2, and the Pd moiety as a Lewis acid activates the carbonyl group to facilitate the attack by the enolate to provide 11 and 13 [2]. 

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,... 

Few other asymmetrie reactions have been performed using insoluble or soluble polymer-supported ligands. The first example is a Mukaiyama-aldol condensation between silyl ketene acetal and different aldehydes using polymeric Box analog of 99 as chiral ligands and Cu(OTf)2 as metal soiu ce in water (Scheme 147) [216]. When using benzaldehyde as substrate, yields were very low (12-34%) and ee were moderate (40-62%) whatever the polymer-supported Box. The same level of enantioseleetivity was observed with other aldehydes while the yield was better with all the ligand/Cu complexes used. 

The aldehyde 157 was prepared according to the sequence in the synthesis of Evans total synthesis of callipeltoside A (Scheme 33) [75]. The vinylidene asymmetric Mukaiyama aldol reaction of a-oxy aldehyde 159 and silyl ketene acetal 160 catalyzed by Cu-pybox complex 161 [76] furnished 5-hydroxy-a, /l-unsaturated ester 162 in 95% ee, which was reduced to yield 157. 

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