Asymmetric allylation, Baylis-Hillman carbonates

Chen and coworkers employed the cinchona alkaloid-derived catalyst 26 to direct Mannich additions of 3-methyloxindole 24 to the A-tosylimine 25 to afford the all-carbon quaternary center of oxindole 27 with good enantioselectivity (84% ee) [22]. The outcome of this Mannich reaction is notable in that it provided very good selectivity for the anti diastereomer (anti/syn 94 6). The mechanism of asymmetric induction has been suggested to involve a hydrogen bonding network between the cinchona alkaloid 26, the oxindole enolate of 24, and the imine electrophile 25 (Scheme 7). Asymmetric allylic alkylation of oxindoles with Morita-Baylis-Hillman carbonates has been reported by the same group [23]. 

Baylis-Hillman carbonate is a good substrate for asymmetric allylic substitution reaction, and various nucleophiles have been involved in this transformation. As shown in Scheme 9.36, the intermediate 72 (mechanistically formed by Michael... 

Morita-Baylis-Hillman carbonates undergo an hydrolysis in the presence of the asymmetric organocatalyst, hydroquinidine[anthraquinone-l,4-diyl] diether, and Cap2 in aqueous iV,iV-dimethylacetamide, yielding the allylic alcohol Tracer studies using showed that water is the nucleophile in the hydrolysis reaction. It is... 

An asymmetric allylic alkylation of Morita-Baylis-Hillman carbonates and )0-keto sul-fones by modified cinchona alkaloids as catalysts gives products that undergo a Smiles rearrangement-sulfinate addition cascade to functionalized five-membered cyclic sul-fones (Scheme 172) ... 

The asymmetric allylic substitution reaction of Morita-Baylis-Hillman carbonates (226) with diphenyl phosphite in the presence of chiral multifunctional thiourea-phosphine catalyst (228) provided allylic phosphites (227) in high yields and with excellent enantioselectivities (Scheme 76). 

Kissel, Ramsden, and other researchers at Pfizer and Chirotech jointly published a novel chiral synthesis of pregabalin (2) in 2003 based on asymmetric hydrogenation (Burk et al., 2001, 2003). Their synthesis started with the condensation of isobutyralde-hyde with acrylonitrile under Baylis-Hillman conditions to give allylic alcohol 65. This alcohol was activated as the carbonate 66 and subjected to palladium-catalyzed car-bonylation conditions to give cyanoester 67. The ester 67 was hydrolyzed and converted to... 

Trost and coworkers have shown that Baylis-Hillman adducts can be efficiently derace-mized by Pd2dba3-CHCl3 catalyzed reaction of the corresponding carbonates 55 with phenols 56 in the presence of chiral C2-symmetric P,N-ligands (Scheme 11) [44], The strategy follows a dynamic kinetic asymmetric transformation process via jr-allyl palladium chemis-... 

A Lewis base-assisted Brpnsted base catalysis strategy has been used for direct asymmetric vinylogous alkylation of allylic sulfones with Morita-Baylis-Hillman (MBH) carbonates, in which a strong Brpnsted base, f-butoxy anion, generated in situ from a tertiary amine catalyst and MBH carbonate, is crucial in activating unstabilized nucleophiles. The y-regio-selective alkylation products were obtained with good to excellent enantiomeric excess (up to 98% ee) values when catalysed by a modified cinchona alkaloid. 

The introduction of the activated allylic bromides and Morita-Baylis-Hillman acetates and carbonates pioneered the development of a number of phosphine-catalyzed reactions in subsequent years [45]. Interestingly, the asymmetric variant of this type of transformation only appeared in the literature seven years later. In 2010, Tang, Zhou, and coworkers disclosed a highly enantioselective intramolecular ylide [3-f2] annulation using spirobiindane-based phosphine catalyst 31 (Scheme 20.27). BINAP was found inactive in this reaction even at an elevated temperature (70°C). Notably, both optically active benzobicyclo[4.3.0] compounds 32 and 32 with three continuous stereogenic centers could be obtained as major products in high yields and stereoselectivities just by a choice of an additive [Ti(OPr )4], which can block the isomerization of the double bond [46]. 

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