1068601-77-3Relevant academic research and scientific papers
Addressing time-dependent CYP 3A4 inhibition observed in a novel series of substituted amino propanamide renin inhibitors, a case study
Chen, Austin,Dubé, Daniel,Dubé, Laurence,Gagné, Sébastien,Gallant, Michel,Gaudreault, Mireille,Grimm, Erich,Houle, Robert,Lacombe, Patrick,Laliberté, Sébastien,Liu, Suzanna,MacDonald, Dwight,MacKay, Bruce,Martin, David,McKay, Dan,Powell, David,Lévesque, Jean-Fran?ois
, p. 5074 - 5079 (2010)
Time-dependent inhibitors of CYPs have the potential to perpetrate drug-drug interactions in the clinical setting. After finding that several leading compounds in a novel series of substituted amino propanamide renin inhibitors inactivated CYP3A4 in an NA
Stereocontrolled alkylative construction of quaternary carbon centers
Kummer, David A.,Chain, William J.,Morales, Marvin R.,Quiroga, Olga,Myers, Andrew G.
supporting information; experimental part, p. 13231 - 13233 (2009/02/06)
Protocols for the stereodefined formation of α,α-disubstituted enolates of pseudoephedrine amides are presented followed by the implementation of these in diastereoselective alkylation reactions. Direct alkylation of α,α-disubstituted pseudoephedrine amide substrates is demonstrated to be both efficient and diastereoselective across a range of substrates, as exemplified by alkylation of the diastereomeric pseudoephedrine α-methylbutyramides, where both substrates are found to undergo stereospecific replacement of the α-C-H bond with α-C-alkyl, with retention of stereochemistry. This is shown to arise by sequential stereospecific enolization and alkylation reactions, with the alkyl halide attacking a common π-face of the E- and Z-enolates, proposed to be opposite the pseudoephedrine alkoxide side chain. Pseudoephedrine α-phenylbutyramides are found to undergo highly stereoselective but not stereospecific α-alkylation reactions, which evidence suggests is due to facile enolate isomerization. Also, we show that α,α-disubstituted pseudoephedrine amide enolates can be generated in a highly stereocontrolled fashion by conjugate addition of an alkyllithium reagent to the s-cis-conformer of an α-alkyl-α,β-unsaturated pseudoephedrine amide, providing α,α-disubstituted enolate substrates that undergo alkylation in the same sense as those formed by direct deprotonation. Methods are presented to transform the α-quaternary pseudoephedrine amide products into optically active carboxylic acids, ketones, primary alcohols, and aldehydes. Copyright
