Enol silanes diastereoselectivity

Q Chiral racemic y-alkyl-substituted enones the titanium(IV) chloride mediated addition of enol silanes and silylketene acetals to 7 shows high induced diastereoselection (diastereomeric ratios from 89 11 to more than 97 3) and the major isomer 8 results from addition of the enolsilane with ul topicity288. Re face attack on the S enantiomer of 7.)... 

In 2000, Tanino and his co-workers developed the novel [5- -2]-cycloaddition reaction of a propargyiic cation equivalent bearing allylic silane 17 with enol silane 18 to give the corresponding cycloheptyne complexes 19 in good yields with an excellent diastereoselectivity (Scheme 3). While ceric ammonium nitrate (CAN) is generally used to... 

In 1993, Nicholas and his co-worker developed the stereospecific propargylic alkylation of chiral propargylic alcohols 30 with enol silanes 31 by using a stoichiometric amount of [Co2(CO)5L] (L = phosphite), but separation procedures of the produced diastereoisomers are necessary twice on the way to obtain the compounds specifically alkylated at the propargylic position 32 (Scheme 5). In 2001, Montana and his co-worker reported the diastereo-selective Nicholas alkylation of propargylic acetal complexes 33 bearing a chiral auxiliary with various enol silanes 34 (Equation (14)). A high diastereoselectivity is observed, but unfortunately, only low to moderate enantioselec-tivities are achieved in all cases. 

Heathcock, C. H., Davidsen, S. K., Hug, K. T., Flippin, L. A. Acyclic stereoselection. 36. Simple diastereoselection in the Lewis acid mediated reactions of enol silanes with aldehydes. J. Org. Chem. 1986, 51,3027-3037. 

The same bisoxazoline Cu(II) and Sn(II) complexes have been utilized successfully in the corresponding propionate aldol addition reactions (Scheme 8-7). A remarkable feature of these catalytic processes is that either syn or anti simple dia-stereoselectivity may be accessed by appropriate selection of either Sn(II) or Cu(II) complexes. The addition of either - or Z-thiopropionate-derived silyl ke-tene acetals catalyzed by the Cu(II) complexes afford adducts 78, 80, and 82 displaying 86 14-97 3 syn anti) simple diastereoselectivity. The optical purity of the major syn diastereomer isolated from the additions of both Z- and i -enol silanes were excellent (85-99% ee). The stereochemical outcome of the aldol addition reactions mediated by Sn(Il) are complementary to the Cu(U)-catalyzed process and furnish the corresponding anp -stereoisomers 79, 81, and 83 as mixtures of 10 90-1 99 syn/anti diastereomers in 92-99% ee. 

The most intensely studied aldol addition mechanisms are those beUeved to proceed through closed transition structures, which are best understood within the Zimmerman-Traxler paradigm (Fig. 5) [Id]. Superposition of this construct on the Felkin-Ahn model for carbonyl addition reactions allows for the construction of transition-state models impressive in their abiUty to account for many of the stereochemical features of aldol additions [50a, 50b, 50c, 51]. Moreover, consideration of dipole effects along with remote non-bonding interactions in the transition-state have imparted additional sophistication to the analysis of this reaction and provide a bedrock of information that may be integrated into the further development and refinement of the corresponding catalytic processes [52a, 52b]. One of the most powerful features of the Zimmerman-Traxler model in its application to diastereoselective additions of chiral enolates to aldehydes is the correlation of enolate geometry (Z- versus E-) with simple di-astereoselectivity in the products syn versus anti). Consequently, the analyses of catalytic, enantioselective variants that display such stereospecificity often invoke closed, cyclic structures. Further studies of these systems are warranted, since it is not clear to what extent such models, which have evolved in the context of diastereoselective aldol additions via chiral auxiliary control, are applicable in the Lewis acid-catalyzed addition of enol silanes and aldehydes. 

Chiral silyl ketene acetals (Il)-(20) were recently introduced for diastereoselective aldol-type additions. Camphor derivatives (11)-(16) are conformationally rigid with one diastereotopic face of the enol silane sterically shielded. - A -Methylephedrine derivatives (17)-(20) are likely to bind to TiCU through the NMe2 group with consequent dramatic conformational constraint.As a result the Lewis acid mediated additions to C=X occur in a highly stereoselective way. The chiral auxiliaries can then be removed (and recycled) by reduction, saponification or displacement with various nucleophiles to give useful synthetic intermediates. 

Numerous in-depth mechanistic studies have been performed on the Mukaiyama aldol reaction. " Although various mechanisms exist in the literature that take into account the various roles of the numerous catalysts used for the enantio- and diastereoselective Mukaiyama aldol reaction, the commonly accepted mechanism accounting for bond formation is shown below.The reaction begins with the coordination of a Lewis acid with aldehyde 4 to form complex 5. Due to its enhanced electrophilicity, complex 5 is attacked by the 7t-bond of the enol silane 6, giving rise to resonance stabilized cation 7. At this point, either intermolecular silyl cleavage upon hydrolysis or intramolecular silyl transfer to the product hydroxyl group occurs to give products such as 8 or 9. 

In contrast, the Mukaiyama aldol reaction used in the Heathcock synthesis of the C29-C44 fragment of spongistatin proceeded with comparatively reduced diastereoselectivity. The stereochemically complex enol silane 30 was eoupled to 29, a 2,3-57 -p-alkoxy aldehyde, resulting in... 

Acetals can be effectively utilized as electrophiles for enol silane substrates under Lewis acidic conditions. As demonstrated by Williams and coworkers, the diastereoselective ZnC -catalyzed Mukaiyama aldol process between enol silane 45 and acetal 44 occurred to produce 46. Thus, the E-unsaturated ketone of the marine macrolide leucascandrolide A was directly installed with a high level of diastereoselectivity resulting from axial addition to the resulting 6-membered oxocarbenium ion. Similar results were... 

The highly electrophilic cationic bis(8-quinolinolato)aluminum complex 407 enabled Yamamoto and coworkers to perform Mukaiyama-Michael additions of silyl enol ethers to crotonylphosphonates 406. The procedure was not only applicable to enol silanes derived from aryl methyl and alkyl methyl ketones (a-unsubstituted silicon enolates) but also to several cycfic a-disubstituted silyl enol ethers, as illustrated for the derivatives of a-methyl tetralone and indanone 405 in Scheme 5.105. Despite the steric demand of that substitution pattern, the reaction occurred in relatively high chemical yield with varying diastereoselectivity and excellent enantiomeric excess of the major diastereomer. The phosphonate residue was replaced in the course of the workup procedure to give the methyl esters 408. The protocol was extended inter alia to the silyl enol ether of 2,6,6-tetramethylcyclohexanone. The relative and absolute configuration of the products 408 was not elucidated [200]. 

The reaction of substituted aziridinyl enolsilane 224 and furan also afforded good yields of cycloadducts with good diastereoselectivity (Scheme 18.50). Similar to the epoxy enolsilanes (Section 18.1.3.7), the cycloaddition of (Z)-enol-silane 229 and cyclopentadiene was stereospecific with respect to the enol geometry and yielded the corresponding endo and exo cycloaddition products. 

In the addition of an achiral enolate to an aldehyde bearing a stereogenic center at Ca, the jr-facial selectivity can usually be predicted by the Felkin-Anh model (158 see also Chapter 2) [83]. However, simple 1,2-diastereoin-duction with enolates derived from typical metals such as lithium, boron, and titanium is often insufficient to be synthetically useful [16, 20). Higher levels of diastereoselectivity are generally obtained by use of enol silanes [34], as reported by Heathcock (Equation 14) [84]. 

In investigations of double diastereodifferentiating Mukaiyama aldol reactions, Evans demonstrated that the coupling of end silane 195 either to aldehyde 196 or to aldehyde 198 affords the Felkin products 197 and 199, respectively, with excellent diastereoselectivity (Scheme 4.21) [36]. Because of the involvement of open transition states in these aldol reactions, no direct correlation was found between the starting end silane geometry and the observed simply selectivity (syn versus anti). This contrasts with the simple diastereoselectivity typically observed for cis- and trans-metal enolates that react through cyclic Zimmerman-Traxler transition states. By this strategy, the addition of enol silane 201 to 200 provided an advanced intermediate 202 in the synthesis of 6-deoxyerythronolide B (187, Scheme 4.22) [97]. 

The tandem aldol-allylation strategy is also applicable to stereocontroDed poly-ketide/macrolide synthesis. ( )- and (Z)-Crotyl(enol)(pinacolato)silanes 49 and 51 react stereoselectively with cyclohexanecarbaldehyde to produce 1,3-diols 50 and 52, respectively, with high diastereoselectivities (Scheme 5.13) [20]. It is noteworthy that the reaction of ( , )-crotyl(enol)silane 53 is capable of constructing of... 

Scheme 3.7. Diastereoselective formation of /S-silyl ( )- or (Z)-ester enolates by silylcuprate conjugate addition followed by alkylation with aldehydes [49]. Stereoselective synthesis of ( )-and (Z)-allyl silanes [50].

The introduction of the allylic silane moiety required for the intermolec-ular Hosomi-Sakurai reaction is depicted in Scheme 16. Following the formation of the enol triflate 97, a Stille coupling provided excess to the allylic alcohol 98 [51]. The allylic alcohol (98) was endowed with a phosphate leaving group for the subsequent allylic substitution. Utilizing a trimethylsilyl cuprate as nucleophile for the 5 2 reaction, the allylic phosphate was converted into the allylic silane 89. A useful substrate-induced diastereoselectivity in favour of (14i )-89 was encountered at small scale but decreased significantly upon up-scaling. 

Inspired by the previous results, Leighton et al. reported the enantioselective [3 + 2] acylhydrazone-enol ether cycloaddition reaction by employing the same pseudoephedrine-based chiral silane. The pyrazohdine product was obtained in 61% yield with 6 1 dr and 77% ee in 24 h. The use of tert-butyl vinyl ether led to an improvement in both diastereoselectivity and enantioselectivity as shown in Scheme 34 [108]. 

The concept of a diastereoselective Friedel-Crafts alkylation of a-chiral benzyl alcohols was first examined by Bach and coworkers [62, 63]. The initial protocol required stoichiometric amounts of strong Brpnsted acids like HBF4 and was followed by a more valuable methodology in which catalytic amounts of AuC L were employed for the diastereoselective functionalization of chiral benzyl alcohols [64], Beside arenes, allyl silanes, 2,4-pentanediones and silyl enol ethers have been used as nucleophiles. Depending on the diastereodiscriminating group and on the catalyst (Brpnsted or Lewis acid), the authors observed either the syn or the anti diastereoisomer as the major product. 

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