Silyl ketene acetals diastereoselectivity

Diastereoselection is also observed in the catalyzed [titanium tetrachloride (TiCI4)13, trimethyl-silyltrifluoromethanesulfonate (TMSTf)l4, zinc iodide (Znl2)15] reactions of silyl ketene acetal 1 with imines 2, The ami configuration of the product 3 dominates. 

Hepatite Virus NS3/4A having the pyrrolidine-5,5-trans-lactam skeleton [83], starting from (R)- and (S)-methionine, respectively. The key step is the addition of the proper silyl ketene acetal to an iminium ion, e.g., that generated by treatment of the intermediate 177 with boron trifluoride, which provided the adduct 178 with better diastereoselectivity than other Lewis acids. Inhibitors of hepatitis C virus NS3/4A were efficiently prepared by a similar route from (S)-methionine [83]. The addition of indole to a chiral (z-amino iminium ion was a completely diastereoselective step in a reported synthesis of tilivalline, a natural molecule which displays strong cytotoxicity towards mouse leukemia L 1210 [84]. 

Unsaturated acyl derivatives of oxazolidinones can be used as acceptors, and these reactions are enantioselective in the presence of chiral to-oxazoline catalysts.321 Silyl ketene acetals of thiol esters are good reactants and the stereochemistry depends on the ketene acetal configuration. The Z-isomer gives higher diastereoselectivity than the Zf-isomer. 

If HMPA is included in the solvent, the Z-enolate predominates.236,238 DMPU also favors the Z-enolate. The switch to the Z-enolate with HMPA or DMPU is attributed to a looser, perhaps acyclic TS being favored as the result of strong solvation of the lithium ion. The steric factors favoring the -TS are therefore diminished.239 These general principles of solvent control of enolate stereochemistry are applicable to other systems.240 For example, by changing the conditions for silyl ketene acetal formation, the diastereomeric compounds 17a and 17b can be converted to the same product with high diastereoselectivity.241... 

It should be noted that specially purified individual stereoisomers of six-membered cyclic nitronates were used in coupling with silyl ketene acetal. Hence, the mechanistic model of the C,C-coupling reaction can be discussed on the basis of the configurations of the stereocenters of the starting nitronates of intermediate cations (357) (see Section 3.5.2.1), and the resulting tetrahydro-oxazines (358) (for more details, see below). It should be noted that most of C,C-coupling reactions of six-membered cyclic nitronates with silyl ketene acetal are characterized by a very high diastereoselectivity. 

Besides their application in asymmetric alkylation, sultams can also be used as good chiral auxiliaries for asymmetric aldol reactions, and a / -product can be obtained with good selectivity. As can be seen in Scheme 3-14, reaction of the propionates derived from chiral auxiliary R -OH with LICA in THF affords the lithium enolates. Subsequent reaction with TBSC1 furnishes the 0-silyl ketene acetals 31, 33, and 35 with good yields.31 Upon reaction with TiCU complexes of an aldehyde, product /i-hydroxy carboxylates 32, 34, and 36 are obtained with high diastereoselectivity and good yield. Products from direct aldol reaction of the lithium enolate without conversion to the corresponding silyl ethers show no stereoselectivity.32... 

Silyl enol ethers have also been used as a trap for electrophilic radicals derived from a-haloesters [36] or perfluoroalkyl iodides [32]. They afford the a-alkylated ketones after acidic treatment of the intermediate silyl enol ethers (Scheme 19, Eq. 19a). Similarly, silyl ketene acetals are converted into o -pcriluoroalkyl esters upon treatment with per fluoro alkyl iodides [32, 47]. The Et3B/02-mediated diastereoselective trifluoromethylation [48,49] (Eq. 19b) and (ethoxycarbonyl)difluoromethylation [50,51] of lithium eno-lates derived from N-acyloxazolidinones have also been achieved. More recently, Mikami [52] succeeded in the trifluoromethylation of ketone enolates... 

Denmark utilized chiral base promoted hypervalent silicon Lewis acids for several highly enantioselective carbon-carbon bond forming reactions [92-98]. In these reactions, a stoichiometric quantity of silicon tetrachloride as achiral weak Lewis acid component and only catalytic amount of chiral Lewis base were used. The chiral Lewis acid species desired for the transformations was generated in situ. The phosphoramide 35 catalyzed the cross aldolization of aromatic aldehydes as well as aliphatic aldehydes with a silyl ketene acetal (Scheme 26) [93] with good yield and high enantioselectivity and diastereoselectivity. 

Three years after the discovery of the asymmetric BINOL phosphate-catalyzed Mannich reactions of silyl ketene acetals or acetyl acetone, the Gong group extended these transformations to the use of simple ketones as nucleophiles (Scheme 25) [44], Aldehydes 40 reacted with aniline (66) and ketones 67 or 68 in the presence of chiral phosphoric acids (R)-3c, (/ )-14b, or (/ )-14c (0.5-5 mol%, R = Ph, 4-Cl-CgH ) to give P-amino carbonyl compounds 69 or 70 in good yields (42 to >99%), flnfi-diastereoselectivities (3 1-49 1), and enantioselectivities (72-98% ee). 

Allylic esters of fluoroacetic acid were used in the Ireland silyl ketene acetal rearrangement procedures by the Welch group at Albany [164]. For example, Eq. (53) shows a highly diastereoselective rearrangement which formed an early stage in syntheses of 2,3-dideoxy-2-fluoro-3-C-methyl pentose nucleosides [165, 166]. If a stereoselective synthesis of a functionalised monofluorocompound is... 

This reaction, also, has been performed diastereoselectively.461 Allylic silanes R.2C=CHCH2SiMe3 can be used instead of silyl enol ethers (the Sakurai reaction). 462 Similarly, silyl ketene acetals, e.g., 56, give 8-keto esters, in MeN02 as solvent, for example,463... 

In contrast to titanium(IV) tetrachloride, which causes polymerization of a,3-unsaturated esters, aluminum triflate88 or aluminum-impregnated montmorillonite87b are excellent promoters of silyl ketene acetal additions to a,(3-unsaturated esters (Scheme 35). Similarly, the addition of silyl ketene acetals and enol silyl ethers to nitroalkenes, followed by Nef-type work-up, affords y-keto esters (216) and y-di-ketones (218), respectively (Scheme 35).89a>89b Mechanistically, the y-diketones (218) arise from Nef-type hydrolysis of an initial nitronate ester (217).89e 89d Mukaiyama reports that SbCls-Sn(OTf)2 catalyzes diastereoselective anti additions of silyl ketene acetals, silyl thioketene acetals and enol silyl ethers to a,(3-unsaturated thioesters (219).90... 

Vinyl sulfoxides (221), which are aldehyde a-cation equivalents, and vinylthiolium ions (230), which are a.jj-unsaturated carbonyl 3-cation equivalents, are also suitable acceptors for silyl ketene acetals and enol silyl ethers (Scheme 36). Kita reports that the bulky r-butyldimethylsilyl ketene acetals and tri-methylsilyl ketene acetals form 1 1 adducts (224) and 1 2 adducts (225) with (221), respectively 91 mechanistically, these additions proceed via an initial Pummerer rearrangement The vinylthiolium ion additions are notable for their synthetic flexibility for example, additions to the ketene dithioacetal (229) proceed with higher diastereoselectivity than the corresponding enolate additions to a,3-unsaturated esters.9 lc,91d... 

The paper reports a highly efficient Claisen rearrangement of a (Z)-silyl ketene acetal (equation I) by use of DMPU to control the stereoselectivity. Use of HMPA lowers the diastereoselectivity from 96 to 84% de. 

The original assignment of the absolute configuration (3S) for products 12 based on a comparison of the optical rotation value with a reported one for the phenyl derivative [27] must be considered uncertain. It would contradict the preferred attack of the nucleophile from the unshielded back side and the stereoselectivity observed in the reaction of A -galactosyl imines 7 with prochiral bis-silyl ketene acetals [28]. N-Galactosyl P-amino acids 13 are produced from bis-silylketene acetals in high yields and excellent diastereoselectivity (Scheme 10). The configuration at the P-position is R. 

First, chemoselective (Chapter 24) conjugate addition of the silyl ketene acetal on the enone is preferred to direct aldol reaction with the aldehyde. Then an aldol reaction of the intermediate silyl enol ether on the benzaldehyde follows. The stereoselectivity results, firstly, from attack of benzalde-hyde on the less hindered face of the intermediate silyl enol ether, which sets the two side chains trans on the cyclohexanone, and, secondly, from the intrinsic diastereoselectivity of the aldol reaction (this is treated in some detail in Chapter 34). This is a summary mechanism. 

Aldol Reactions of Ester Derivatives. The Titanium(IV) C/tlor/dc-catalyzed addition of aldehydes to 0-silyl ketene acetals derived from acetate and propionate esters proceeds with high stereoselectivity. Formation of the silyl ketene acetal was found to be essential for high diastereoselectivity. Treatment of the silyl ketene acetal, derived from deprotonation of the acetate ester with LICA in THF and silyl trapping, with a corresponding aldehyde in the presence of TiCU (1.1 equiv) afforded the addition products in 93 7 diastereoselectivity and moderate yield (51-67%). Similarly, the propionate ester provides the anti-aldol product in high antilsyn selectivity (14 1) and facial selectivity (eq 4). 

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. 

Paternd-Biichi reactions [152] this competition has been investigated for electron-rich alkene substrates for several combinations of carbonyl compounds and electron-donors, e.g. a-diketones and ketene acetals [153], aromatic aldehydes and silyl ketene acetals, and enol ethers. In polar solvents, the assumption of a 1,4-zwitterion as decisive intermediate is reasonable. This situation then resembles the sequence observed for ET-induced thermal [2 -I- 2]-cycloaddition reactions [154]. Both regio- and diastereoselectivity are influenced by this mechanistic scenario. The regioselectivity is now a consequence of maximum charge stabilization and no longer a consequence of the primary interaction between excited carbonyl compound and alkene. Whereas 3-alkoxyoxetanes are preferentially formed from triplet excited aldehydes and enolethers, 2-alkoxyoxetanes result from the reaction of triplet excited ketones or aldehydes and highly electron-rich ketene silylacetals (Scheme 40) [155]. 

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