Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Enol silanes acetals

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]

Energy loss spectroscopy, 30 305-306, 308 a, P-Enoates, Michael reaction of silyl ketene acetal, 38 275 Enol silanes... [Pg.99]

Song and co-workers have taken a variety of aldehydes 344 and treated them with A -adamantyl carbene 1 and trimethylsilyl ketene acetal 345 to produce Mukaiyama aldol products 346 in good yield (Eq. 34) [170], The carbene presumably acts as a Lewis base to activate the silicon - oxygen bond in order to promote reactivity of the enol silane. The catalyst loading can be reduced to as low as 0.05 mol% without a change in yield. [Pg.138]

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. [Pg.129]

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]

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]

This methodology was applied to the asymmetric synthesis of (—)-sedamine (Scheme 10.20). An imine produced in situ from o-anisidine and methyl-5-oxopen-tanoate was alkylated with an enol silane in the presence of silver acetate as catalyst,... [Pg.295]

Kocienski and coworkers [98] have reported the synthesis of 8-membered cyclic ketones by intramolecular aldol reaction of enol silanes and acetals mediated by Lewis acid. [Pg.144]

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]

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]

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]

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. [Pg.241]

For the addition of enol silanes and silyi ketene acetals to vinylthionium ions see Hashimoto, Y. Mukaiyama, T. Chem. Lett. 1986, 1623-1626. [Pg.168]

The discovery of the Lewis acid-mediated addition of enol silanes to aldehydes and acetals by Mukaiyama and coworkers pioneered a novel approach to the construction of molecules via the crossed aldol reaction (Eq. 1) [6a6bj. Importantly, this development proved to be a key lead for the subsequent evolution of this C-C bond forming reaction into a catalytic Si atom-transfer process. Typical enol silanes derived from esters, thioesters, and ketones are unreactive towards aldehydes at ambient temperatures. However, stoichiometric quantities of Lewis acids such as TiCl4, SnCl4, AlClj, BClj, BF3-OEt2, and ZnCl2 were found to pro-... [Pg.940]

The addition reaction of fert-butyl thioacetate-derived silyl ketene acetal produces the corresponding aldol adducts in 84% yield and up to 96% enantiomeric excess (Eq. 16). The enantioselectivity of the products was observed to be optimal with toluene as solvent the use of the more polar dichloromethane consistently produced adducts with 10-15% lower enantiomeric excess. The bulkier ferf-butylthioacetate-derived enol silane was found to lead to uniformly higher levels of enantioselectivity than the smaller S-ethyl thioketene acetal. This process is impressive in that it tolerates a wide range of aldehyde substrates for instance, the aldol addition reaction has been successfully conducted with aldehydes substituted with polar functionaUty such as N-Boc amides, chlorides, esters, and 0-benzyl ethers. A key feature of this system when compared to previously reported processes was the abiUty to achieve high levels of stereoselectivity at 0 °C, in contrast to other processes that commonly prescribe operating temperatures of -78 °C. [Pg.966]

The addition of propionate-derived enol silanes 140 deUvered 1,2-disubstitut-ed aldol adducts 141 and 142 in useful yields and selectivities (Eq. 17) [90]. As in the acetate-derived additions, the selectivity of the process was dependent on the thioalkyl substituent of the silyl ketene acetal 140. The 1,2-syn adduct was obtained from the addition of E-enolsilane and -butyl glyoxylate (Eq. 17, entry 3). Correspondingly, the formation of 1,2-anti adduct was observed in the addition of a-benzyloxy acetaldehyde and the Z-enol silane derived from the ferf-butyl thio ester. [Pg.966]

Treatment of tridentate ligand with Ti(0 Pr)4 and di-ferf-butylsalicyclic acid (163) in toluene followed by evaporation of the solvent afforded an orange complex postulated to be 165, which was shown to be an effective catalyst for the Mukaiyama aldol reaction. Under optimized conditions, the simple methyl acetate-derived enol silane 166 adds to aldehydes in the presence of as little as... [Pg.971]

The catalytic process has found successful application in several natural product total syntheses. In 1996, Simon reported a synthesis of the antitumor dep-sipeptide FR-9001,228 in which the aldol addition reaction of 168 and the ethyl acetate-derived enol silane furnished a key synthetic intermediate (Eq. 23). The enantioselective aldol addition reaction of 168 was conducted with 165 and its enantiomer ent-165 to separately provide both enantiomers of the aldol adducts 169 and 170 (Scheme 14). These were then utilized in the preparation of diastereomeric seco acids 171 and 172 [101]. Macrocyhzation of 172 through a Mitsonobu reaction yielded the desired natural product 173. [Pg.972]

The use of these boryl complexes in catalytic, enantioselective additions to aldehydes by silyl ketene acetals has also been the subject of intense investigation by Yamamoto (Eq. 30) [108]. Although ethyl and benzyl acetate-derived enol silanes furnished racemic products, the phenyl acetate-derived trimethylsilyl ketene acetals proved optimal, giving adducts in up to 84% ee. Additionally, Yamamoto has documented the use of 184 in aldol addition reactions of propionate- and isobutyrate-derived enol silanes (Eqs. 31 and 32). Thus, the addition of the phenyl acetate derived (E)-enol silane afforded adducts as diastereomeric mixtures with the syn stereoisomer displaying up to 97% ee (Eq. 32). [Pg.977]

The addition of phenyl acetate-derived enol silane to benzaldehyde and iso-butyraldehyde in nitromethane utilizing 20 mol % catalyst 195 provided the si-lylated aldol adducts in 80 and 70% ee, respectively. Kiyooka has also document-... [Pg.979]

In analogy to the Yamamoto and Kiyooka catalysts, Mukaiyama aldol addition reactions catalyzed by 202a and 202b are optimal for 0-phenyl acetate-derived enol silanes under conditions wherein the aldehyde substrates are added slowly to the reaction mixture in propionitrile at -78 C. The aldol adducts are isolated for a broad range of aldehydes in excellent yields and up to 92% ee (Eq. 40). The propionate aldol adducts are isolated in good yields, with preference for the syn diastereomer in up to 98% ee (Eq.41) [117]. [Pg.982]

For an enantioselective addition of enol silanes to acetals mediated by a boryl complex incorporating a chiral indolyl group, see Kinugasa M, Harada T, Oku A (1996) J Org Chem 61 6772... [Pg.1007]

Table 3 Ratio of Diastereoisomers in the Lewis Acid Catalyzed Reactions of Enol Silanes with Dimethyl Acetals... Table 3 Ratio of Diastereoisomers in the Lewis Acid Catalyzed Reactions of Enol Silanes with Dimethyl Acetals...
The TiCU-mediated reaction of enol silanes with imines was first introduced by Ojima and coworkers in 1977. The reaction was then extended to several similar substrates, i.e. nitrones, ot-methoxycarba-mates, aminals, 4-acetoxyazetidin-2-one, 40 anj to different Lewis acids, i.e. SnCU, TiCU-(0PH)2, catalytic ZnX2, catalytic TMSOTf, ° to give good yields of the addition products with low levels ( 80 20) or a complete lack of simple stereoselection. Moderate to good anti selectivities were reported in the addition of silyl ketene acetals to imines under particular reaction conditions (equation 9) significant results are summarized in Table 4. [Pg.635]

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. [Pg.636]


See other pages where Enol silanes acetals is mentioned: [Pg.759]    [Pg.30]    [Pg.250]    [Pg.595]    [Pg.521]    [Pg.531]    [Pg.595]    [Pg.421]    [Pg.412]    [Pg.298]    [Pg.979]    [Pg.980]    [Pg.595]    [Pg.195]    [Pg.634]    [Pg.635]    [Pg.642]   
See also in sourсe #XX -- [ Pg.265 , Pg.266 , Pg.267 , Pg.268 , Pg.269 , Pg.270 , Pg.271 , Pg.272 ]




SEARCH



Acetate enolates

Enol acetals

Enol acetates

Enol silanes

Silanes acetals

© 2024 chempedia.info