Ketene silyl thioacetal

Scheme 2.2 illustrates several examples of the Mukaiyama aldol reaction. Entries 1 to 3 are cases of addition reactions with silyl enol ethers as the nucleophile and TiCl4 as the Lewis acid. Entry 2 demonstrates steric approach control with respect to the silyl enol ether, but in this case the relative configuration of the hydroxyl group was not assigned. Entry 4 shows a fully substituted silyl enol ether. The favored product places the larger C(2) substituent syn to the hydroxy group. Entry 5 uses a silyl ketene thioacetal. This reaction proceeds through an open TS and favors the anti product. 

A Mukaiyama-type aldol reaction of silyl ketene thioacetal (48) with an aldehyde with large and small a-substituents (e.g. Ph and Me), catalysed by boron trifluoride etherate, gives mainly the iyn-isomer (49), i.e. Cram selectivity. For the example given, changing R from SiBu Me2 to Si(Pr )3 raises the syn preference considerably, which the authors refer to as the triisopropylsilyl effect. Even when the and R groups are as similar as ethyl and methyl, a syn. anti ratio of 5.4 was achieved using the triisopropylsilyl ketene thioacetal. 

Aldol additions to methyl pyruvate by silyl ketene thioacetals have been shown to proceed in high yield and with excellent asymmetric induction (Eq. 28). This process is an uncommon example of catalytic, asymmetric aldol additions to ketones, providing access to synthetically useful compounds. The remarkable ability of the catalyst to differentiate between subtle steric differences of substituents flanking a 1,2-diketone has been elegantly demonstrated in highly enantioselective additions to 2,3-pentane-dione (Eq. 29). Tlie aldol adduct of 5-ferr-butyl thiopropionate derived silyl ketene acetal afforded 2,3-anh-aldol adduct (>99 1 antilsyn) in 98 % ee and 97 3 chemoselec-tivity for the methyl ketone. 

Keywords / -lactam, silyl ketene thioacetal, imine, scandium triflate... 

Sc(OTf)3 (0.015 g, 0.03 mmol), imine 2 (0.062 g, 0.3 mmol), and silyl ketene thioacetal 1 (0.169 g, 0.6 mmol) were added in this order to a 2-mL glass vial and the resulting dark mixture was stirred for 20 h at room temperature. Di-chloromethane (0.25 mL) was then added and the resulting suspension was purified by flash chromatography with a 10 90 AcOEl/hexane mixture as eluent. The trans-product 3t (0.028 g, 35.5% yield) was eluted first as a thick pale yellow oil followed by the cis-product 3c (0.028 g, 35.5% yield) which was also a thick pale yellow oil. 

Only a few examples in this category were found in the literature and azodi-carboxylic esters are the only animating reagents that have been used. The reactivities appear to be similar to those described above for ester enolates and ketene acetals. The catalyzed enantioselective amination of ketone silyl enol ethers described in Eq. 94 has also been applied to ketene thioacetals.252... 

Thiol esters can be converted to the corresponding 0-silyl ketene thioacetals. The thiol ester (56), under different silylating conditions, can be converted stereoselectively into either the ( )- or the (Z)-isomers of (57). ... 

These and similar catalysts are effective with silyl ketene acetals and silyl ketene thioacetals. ... 

Keten thioacetals (428) are useful synthetic intermediates and a general method for their preparation is reaction of metalated silyl thioacetals with carbonyl derivatives. ... 

Aldol Reactions. The title reagent and its various congeners continue to find application in Mukaiyama-t3fpe aldol reactions as versatile nucleophilic propionate synthons with predictable behavior.For example, the ( )-isomer of the reagent produced the expected major isomer in a boron trifiuoride etherate mediated addition to a complex aldehyde en route to a C19-C35 subunit of swinholide A (eq 14). Remote stereoinduction in Mukaiyama aldol reactions of the reagent with (2-sulfinylphenyl)acetaldehydes was recently observed anti aldol adducts were obtained preferentially regardless of the geometry of the silyl ketene thioacetal employed. ... 

Less traditional Lewis acid catalysts have also been employed to mediate additions of silyl ketene thioacetals to imines and hy-drazones, including scandium(III) triflate and bismuth(III) triflate. In a significant recent advance, Mukaiyama and coworkers reported Lewis base catalyzed additions of the trimethylsilyl congener of the title reagent to iV-sulfonyl aldimines (eq 18). The reaction is tolerant of water and competent Lewis base activators include readily obtained salts such as lithium acetate and lithium benzamide. 

TMAL) reaction sequence for the synthesis of P-lactones. Despite the relatively high diastereoselectivity, the ZnCb mediated aldol reaction was only optimized when smaller silyl and thiol groups of the ketene acetyl were employed for the improved efficiency of the subsequent lactonization. The methodology was utilized in the synthesis of (-)-panicilin D, a pancreatic lipase inhibitor, where the ketene thioacetal 60 was added to aldehyde 59, upon which lactonization followed by deprotection yielded the 3-lactone 61 as a diastereomeric mixture (9.3 1) in modest yield. 

The reactions proceeded efficiently under mild conditions in short time. The silyl enol ethers reacted with the activated acetals or aldehydes at -78 °C to give predominant erythro- or threo-products [136, 137] respectively. In the same manner, the aldol reaction of thioacetals, catalyzed by an equimolar amount of catalyst, resulted in <-ketosulfides [139] with high diastereoselectivity. In the course of this investigation, the interaction of silyl enol ethers with a,]3-unsaturated ketones, promoted by the trityl perchlorate, was shown to proceed regioselec-tively through 1,2- [141] or 1,4-addition [138]. The application of the trityl salt as a Lewis acid catalyst was spread to the synthesis of ]3-aminoesters [142] from the ketene silyl acetals and imines resulting in high stereoselective outcome. 

The reaction of Cjq with silylated nucleophiles [47] requires compounds such as silyl ketene acetals, silylketene thioacetals or silyl enol ethers. It proceeds smoothly and in good yields in the presence of fluoride ions (KF/18-crown-6) (Scheme 3.10). The advantage of the latter synthesis is the realization of the cyclopropanation under nearly neutral conditions, which complements the basic conditions that are mandatory for Bingel reactions. Reaction with similar silyl ketene acetals under photochemical conditions and without the use of F does not lead to methanofullerenes but to dihydrofullerene acetate [48]. 

Evans et al. recently reported the use of structurally well-defined Sn(II) Lewis acids for the enantioselective aldol addition reactions of a-heterosubstituted substrates [47]. These complexes are readily assembled from Sn(OTf)2 and C2-symmetric bis(oxazoline) ligands. The facile synthesis of these ligands commences with optically active 1,2-diamino alcohols, which are themselves readily available from the corresponding a-amino acids. The Sn(II)-bis(oxazoline) complexes were shown to function optimally as catalysts for enantioselective aldol addition reactions with aldehydes and ketone substrates that are suited to putatively chelate the Lewis acid. For example, use of 10 mol % Sn(II) catalyst, thioacetate, and thiopropionate derived silyl ketene acetals added at -78 °C in dichloromethane to glyoxaldehyde to give hydroxy diesters in superb yields, enantioselectivity, and diastereoselectivity (Eq. 27). The process represents an unusual example wherein 2,3-ant/-aldol adducts are obtained stereoselec-tively. 

Aldol reactions. The enantioselectivity in condensations involving silyl enol ethers and silyl ketene acetals (also thioacetals) has been actively pursued. Valuable catalysts include 102, 103. Subsequent to the development of Cj-symmetric... 

As part of a series of studies on the use of BINOL-Ti(IV) complex 53 as a catalyst in a number of C-C bond-forming reactions, Mikami has reported the aldol addition reactions of thioacetate-derived silyl ketene acetals 55, 56 to a collection of highly functionalized aldehydes (Eq. (8.13)) [28]. As little as 5 mol% of the catalyst mediates the addition reaction and furnishes adducts 57 in excellent yields and up to 96% ee. One of the noteworthy features of the Mikami process is the fact that aldehyde substrates containing polar substituents can be successfully employed, a feature exhibited by few other Lewis-acid-catalyzed aldehyde addition reactions. 

Sc(() l f) ( is an effective catalyst of the Mukaiyama aldol reaction in both aqueous and non-aqueous media (vide supra). Kobayashi et al. have reported that aqueous aldehydes as well as conventional aliphatic and aromatic aldehydes are directly and efficiently converted into aldols by the scandium catalyst [69]. In the presence of a surfactant, for example sodium dodecylsulfate (SDS) or Triton X-100, the Sc(OTf)3-catalyzed aldol reactions of SEE, KSA, and ketene silyl thioacetals can be performed successfully in water wifhout using any organic solvent (Sclieme 10.23) [72]. They also designed and prepared a new type of Lewis acid catalyst, scandium trisdodecylsulfate (STDS), for use instead of bofh Sc(OTf) and SDS [73]. The Lewis acid-surfactant combined catalyst (LASC) forms stable dispersion systems wifh organic substrates in water and accelerates fhe aldol reactions much more effectively in water fhan in organic solvents. Addition of a Bronsted acid such as HCl to fhe STDS-catalyzed system dramatically increases the reaction rate [74]. 

Lanthanide triflates and Sc(OTf)3 effectively catalyze conjugate addition of SEE, KSA, and ketene silyl thioacetals under mild conditions (0°C to room temperature, 1-10 mol% catalyst) (Scheme 10.86) [69, 238]. After an aqueous work-up these Lewis acids can be recovered almost quantitatively from the aqueous layer and can be re-used without reduction of fheir catalytic activity. Eu(fod)3 also is effective in not only aldol reactions but also Michael addition of KSA [239]. The Eu(fod)3-catalyzed addition of KSA is highly chemoselective for enones in the presence of ketones. 

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]. 

In 1988, Mukaiyama et al. reported the Sn(OTf)2-50d-catalyzed asymmetric Michael reaction of a trimethylsilyl enethiolate, CH2=C(SMe)SSiMej (up to 70% ee) [243]. It was proposed that the catalytic reaction proceeded via an Sn(II) enethiolate. They also demonstrated that a BINOL-derived oxotitaniurn catalyzes the Michael addition of ketene silyl thioacetals to a-enone with high enantioselectivity (up to 90% ee) [244]. After this pioneering work other research groups developed new reaction systems for enantioselective Mukaiyama-Michael reactions. 

---