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Enol silanes addition

Nucleophilic addition to less reactive ketone carbonyls by Lewis acid activation is also possible. Evans and co-workers have reported enol silane addition to pyruvate esters mediated by chiral copper Lewis acids (Sch. 36) [72]. The aldol reactions proceed with high facial selectivity to provide the tertiary alcohol products 153. The chemical efficiency is, however, reduced when a bulky alkyl group is present at the ketone carbonyl. Addition of more functionalized enol silanes (155) to keto esters enables the establishment of two contiguous chiral centers, a substitution pattern present in a variety of natural products. The stereochemistry of the major product is syn, irrespective of the enol silane geometry. Once again, bidentate coordination of the substrate to the Lewis acid was essential for obtaining high selectivity. [Pg.560]

Fig.4. The Seebach model as applied to enol silane additions to aldehydes emphasizes the incipient steric interactions that result from Burgi-Dimitz constraints... Fig.4. The Seebach model as applied to enol silane additions to aldehydes emphasizes the incipient steric interactions that result from Burgi-Dimitz constraints...
Imines, being neutral species, are less reactive than iminium salts. Consequently, active methylene compounds with pKn values greater than -15-16 must be preactivated as an enolate or enol silane derivative. Lewis acids are sometimes used in reactions with enolates to improve reactivity and stereoselectivity, but in contrast to the reactions of preformed iminium salts, Lewis acids are required in reactions with enol silanes. Additional activation of the active methylene compound or catalysis is not usually required in reactions with more acidic active methylene compounds (pATa values below -15-16). In these reactions, higher acidity not only gives higher enol concentrations but also serves to catalyze the reaction through protonation of the imine. [Pg.915]

Cossy s approach for the synthesis of leucascandrolide A involved an asymmetric allylmetalation to incorporate the stereogenic centers at C(5), C(7), C(9), C(ll) and C(12), and olefin metathesis. Construction of the 2,6-cis- and 2,6-trani-tetr-ahydropyrans was achieved by the Mukaiyama enol silane addition and oxa-conjugate addition reaction, respectively. The synthesis commenced with the... [Pg.82]

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.)... [Pg.991]

Conversion of ketone 80 to the enol silane followed by addition of lithium aluminum hydride to the reaction mixture directly provides the allylic alcohol 81 [70]. Treatment of crude allylic alcohol 81 with tert-butyldimethylsilyl chloride followed by N-b ro m o s u cc i n i m i de furnishes the a-bromoketone 82 in 84 % yield over the two-step sequence from a.p-unsaturated ester 80. Finally, a one-pot Komblum oxidation [71] of a-bromoketone 82 is achieved by way of the nitrate ester to deliver the glyoxal 71. It is worth noting that the sequence to glyoxal 71 requires only a single chromatographic purification at the second to last step (Scheme 5.10). [Pg.122]

Intermolecular cross aldolization of metallo-aldehyde enolates typically suffers from polyaldolization, product dehydration and competitive Tishchenko-type processes [32]. While such cross-aldolizations have been achieved through amine catalysis and the use of aldehyde-derived enol silanes [33], the use of aldehyde enolates in this capacity is otherwise undeveloped. Under hydrogenation conditions, acrolein and crotonaldehyde serve as metallo-aldehyde enolate precursors, participating in selective cross-aldolization with a-ketoaldehydes [24c]. The resulting/ -hydroxy-y-ketoaldehydes are highly unstable, but may be trapped in situ through the addition of methanolic hydrazine to afford 3,5-disubstituted pyridazines (Table 22.4). [Pg.721]

Silyltitanation of 1,3-dienes with Cp2Ti(SiMe2Ph) selectively affords 4-silylated r 3-allyl-titanocenes, which can further react with carbonyl compounds, C02, or a proton source [26]. Hydrotitanation of acyclic and cyclic 1,3-dienes functionalized at C-2 with a silyloxy group has been achieved [27]. The complexes formed undergo highly stereoselective addition with aldehydes to produce, after basic work-up, anti diastereomeric (3-hydroxy enol silanes. These compounds have proved to be versatile building blocks for stereocontrolled polypropionate synthesis. Thus, the combination of allyltitanation and Mukayiama aldol or tandem aldol-Tishchenko reactions provides a short access to five- or six-carbon polypropionate stereosequences (Scheme 13.15) [28],... [Pg.457]

KH/18-crown-6, HMPA "- 13 Scheme 8 Addition of triarylgermanes to alkenes and enol silanes... [Pg.87]

Some of the most impressive advances in the area of catalytic, enantioselective aldol addition reactions have taken place in the development of catalytic methods for enantioselective acetate aldol additions, a reaction type that has long been recalcitrant. Thus, although prior to 1992 a number of chiral-auxiliary based and catalytic methods were available for diastereo- and enantiocontrol in propionate aldol addition reactions, there was a paucity of analogous methods for effective stereocontrol in the addition of the simpler acetate-derived enol silanes. However, recent developments in this area have led to the availability of several useful catalytic processes. Thus, in contrast to the state of the art in 1992, it is possible to prepare acetate-derived aldol fragments utilizing asymmetric catalysis with a variety of transition-metal based complexes of Ti(IV), Cu(II), Sn(II), and Ag(I). [Pg.525]

Mikami has carried out a number of investigations aimed at elucidating mechanistic aspects of this Si-atom transfer process. In particular, when the aldol addition reaction was conducted with a 1 1 mixture of enoxysilanes 60 and 62, differentiated by the nature of the 0-alkyl and 0-silyl moieties, only the adducts of intramolecular silyl-group transfer 63 and 64 are obtained (Scheme 8B2.6). This observation in addition to results obtained with substituted enol silanes have led Mikami to postulate a silatropic ene-like mechanism involving a cyclic, closed transition-state structure organized around the silyl group (Scheme 8B2.6). [Pg.525]

Significant efforts have extended the scope of catalytic enantioselective Mukaiyama aldol addition reactions beyond the acetate and propionate enoxysilanes and have been used traditionally. Recent reports describe novel addition reactions of silyl dienolates along with isobutyrate-derived enol silanes. [Pg.533]

Aldol Addition. A catalyst generated upon treatment of Cu(OTf)2 with the (5,5)-r-Bu-box ligand has been shown to be an effective Lewis acid for the enantioselective Mukaiyama aldol reaction. The addition of substituted and unsubstituted enolsilanes at -78 °C in the presence of 5 mol % catalyst was reported to be very general for various nucleophiles, including silyl dienolates and enol silanes prepared from butyrolactone as well as acetate and propionate esters. [Pg.111]

Substantial improvements of the ee of another desymmetrization process are also observed in the presence of LiCl (Sch. 16). Results obtained for formation of enol silane 36 show that when a base is reacted with the ketone before MeaSiCl treatment (external quench EQ method), the ee is low (33 %). Under the external quench technique in the presence of LiCl (10 mol %), however, the ee is enhanced to 84 %, comparable with the 82 % ee obtained by an internal quench technique (IQ method addition of MeaSiCl before treatment with 35). It should be noted that unlike the E/Z ratios and ee mentioned above (Sch. 12), no subsequent drop in ee is seen when 1 equiv. or more LiCl is used. Further experiments involving the LiCl-assisted aldol reaction of tropinone 37 also resulted in increased ee [57]. [Pg.22]

Activation of C=N double bonds by copper Lewis acids for nucleophilic addition has also been reported (Sch. 37) [73]. The a-imino ester 157 undergoes alkylation at the imine carbon with a variety of nucleophiles when catalyzed by copper Lewis acids. The presence of the electron-withdrawing ester group increases the reactivity of the imine and also assists in the formation of a stable five-membered chelate with the Lewis acid. Evidence for Cu(I) Lewis-acid catalysis and a tetrahedral chelate was obtained by FTIR spectroscopy, from the crystal structure of the catalyst, and from several control experiments. The authors rule out the intermediacy of a copper enol-ate in these transformations. The asymmetric alkylation of A,0-acetals with enol silanes mediated by a copper Lewis acid proceeding with high selectivity has been reported [74],... [Pg.560]

Mukaiyama aldol reaction Lewis acid mediated addition of enol silanes to carbonyl compounds. 298... [Pg.514]

The pioneering discovery by Mukaiyama in 1974 of the Lewis acid mediated aldol addition reaction of enol silanes and aldehydes paved the way for subsequent explosive development of this innovative method for C-C bond formation. One of the central features of the Mukaiyama aldol process is that the typical enol silane is un-reactive at ambient temperatures with typical aldehydes. This reactivity profile allows exquisite control of the reaction stereoselectivity by various Lewis acids additionally, it has led to the advances in catalytic, enantioselective aldol methodology. Recent observations involving novel enol silanes, such as enoxy silacyclobutanes and O-si-lyl M(9-ketene acetals have expanded the scope of this process and provided additional insight into the mechanistic manifolds available to this versatile reaction. [Pg.232]


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See also in sourсe #XX -- [ Pg.273 , Pg.274 , Pg.275 , Pg.276 , Pg.277 , Pg.278 ]




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