1007229-49-3Relevant articles and documents
Formation of carbocycles by intramolecular conjugate displacement: Scopeand mechanistic insights
Wang, Lihong,Prabhudas, Bodhuri,Clive, Derrick L. J.
supporting information; experimental part, p. 6003 - 6012 (2009/09/25)
A detailed study has been made of a method of ring closure categorized as an all-carbon intramolecular conjugate displacement (ICD). This reaction involves intramolecular addition of a carbanion, which is stabilized by at least one electron-withdrawing group, to a Michael acceptor which has a leaving group in an allylic position. The process formally resembles a combination of Michael addition and S N2' displacement. The overall result is formation of a ring with loss of the allylic leaving group and shift of the original double bond to a new location spanning the positions of the electron-withdrawing substituent of the Michael acceptor subunit and the original allylic leaving group. The starting materials are easily prepared by a selenium-based version of the Morita-Baylis-Hillman reaction. The cyclizations are transition metal free and occur under mild conditions, using DBU or Cs 2CO 3 inMeCN or THF. Acetate is a suitable leaving group and the electron-withd rawing substituent of the Michael acceptor unit can be CO 2R,SO 2Ph, or CN. Six- and seven-membered rings are formed effi ciently, and complex structures, such as those resembling the core of CP-225,917, are easily assembled. The products of these ICD reactions are themselves classical Michael acceptors. A range of mechanisms probably operates, depending on the structure of the starting material and the reaction conditions, but conclusive evidence for a stepwise mechanism was obtained in a suitably biased case, while other observations are compatible with a concerted process or a stepwise path involving a short-lived carbanion that evades capture by a proton source.
All-carbon intramolecular conjugate displacement reactions: An effective route to carbocycles
Prabhudas, Bodhuri,Clive, Derrick L. J.
, p. 9295 - 9297 (2008/12/22)
(Chemical Equation Presented) Working together: Synergy between Michael addition and SN2′ displacement allows stabilized carbanions or the nucleophilic carbon atoms of enamines to undergo intramolecular addition to an α,β-unsaturated ester unit bearing an allylic leaving group to generate unsaturated carbocycles (see scheme). The starting esters are available by a selenium-based alternative to the classical Baylis-Hillman reaction, and complex structures can be assembled.
