1448527-67-0Relevant articles and documents
Catalytic Asymmetric Crotylation of Aldehydes: Application in Total Synthesis of (-)-Elisabethadione
O'Hora, Paul S.,Incerti-Pradillos, Celia A.,Kabeshov, Mikhail A.,Shipilovskikh, Sergei A.,Rubtsov, Aleksandr E.,Elsegood, Mark R. J.,Malkov, Andrei V.
, p. 4551 - 4555 (2015)
A new, highly efficient Lewis base catalyst for a practical enantio- and diastereoselective crotylation of unsaturated aldehydes with E- and Z-crotyltrichlorosilanes has been developed. The method was employed as a key step in a novel asymmetric synthesis of bioactive serrulatane diterpene (-)-elisabethadione. Other strategic reactions for setting up the stereogenic centers included anionic oxy-Cope rearrangement and cationic cyclization. The synthetic route relies on simple, high yielding reactions and avoids use of protecting groups or chiral auxiliaries.
Optimization of Catalyst Structure for Asymmetric Propargylation of Aldehydes with Allenyltrichlorosilane
Vaganov, Vladimir Yu.,Fukazawa, Yasuaki,Kondratyev, Nikolay S.,Shipilovskikh, Sergei A.,Wheeler, Steven E.,Rubtsov, Aleksandr E.,Malkov, Andrei V.
, p. 5467 - 5474 (2020/10/19)
The design of catalysts for asymmetric propargylations remains a challenging task, with only a handful of methods providing access to enantioenriched homopropargylic alcohols. In this work, guided by previously reported computational predictions, a set of
Stereoselective Synthesis of Atropisomeric Bipyridine N,N′-Dioxides by Oxidative Coupling
Fukazawa, Yasuaki,Vaganov, Vladimir Yu.,Shipilovskikh, Sergei A.,Rubtsov, Aleksandr E.,Malkov, Andrei V.
supporting information, p. 4798 - 4802 (2019/06/17)
Bipyridine N,N′-dioxide is a structural fragment found in many bioactive compounds. Furthermore, chiral analogues secured their place as powerful Lewis base catalysts. The scope of the existing methods for the synthesis of atropisomeric bipyridine N,N′-di
Mechanistic dichotomy in the asymmetric allylation of aldehydes with allyltrichlorosilanes catalyzed by chiral pyridine N-oxides
Malkov, Andrei V.,Stoncius, Sigitas,Bell, Mark,Castelluzzo, Fabiomassimo,Ramirez-Lopez, Pedro,Biedermannova, Lada,Langer, Vratislav,Rulisek, Lubomir,Kocovsky, Pavel
, p. 9167 - 9185 (2013/07/26)
Detailed kinetic and computational investigation of the enantio- and diastereoselective allylation of aldehydes 1 with allyltrichlorosilanes 5, employing the pyridine N-oxides METHOX (9) and QUINOX (10) as chiral organocatalysts, indicate that the reaction can proceed through a dissociative (cationic) or associative (neutral) mechanism: METHOX apparently favors a pentacoordinate cationic transition state, while the less sterically demanding QUINOX is likely to operate via a hexacoordinate neutral complex. In both pathways, only one molecule of the catalyst is involved in the rate- and selectivity-determining step, which is supported by both experimental and computational data. Copyright
