259754-41-1Relevant academic research and scientific papers
N-Acylation of Oxazolidinones via Aerobic Oxidative NHC Catalysis
Ta, Linda,Axelsson, Anton,Sundén, Henrik
, p. 12261 - 12268 (2018)
The first N-acylation of synthetically useful oxazolidinones with aldehydes using aerobic oxidative NHC catalysis is reported. The reaction offers a broad scope of functionalized oxazolidinones in good to excellent yields. Careful choice of electron transfer mediators proved pivotal to achieve efficient aerobic N-acylation, which has previously proven difficult using NHC catalysis. The methodology allows a mild entry to acylated oxazolidinones, avoiding the use of hazardous and reactive prefunctionalized substrates.
Acrylic acid compounds as well as preparation method, pharmaceutical composition and application thereof
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Paragraph 0167-0170; 0179-0180, (2019/12/02)
The invention provides acrylic acid compounds as well as a preparation method, a pharmaceutical composition and application thereof, and particularly provides compounds as shown in the following formula I. The definition of each group is as shown in the s
Rational Design of Highly Diastereoselective, Organic Base-Catalyzed, Room-Temperature Michael Addition Reactions
Soloshonok, Vadim A.,Cai, Chaozhong,Hruby, Victor J.,Van Meervelt, Luc,Yamazaki, Takashi
, p. 6688 - 6696 (2007/10/03)
Via the rational design of a single-preferred transition state, stabilized by electron donor - acceptor-type attractive interactions, structural and geometric requirements for the corresponding starting compounds have been determined. The Ni(II) complex of the Schiff base of glycine with o-[N-α-picolylamino]acetophenone, as a nucleophilic glycine equivalent, and N-(trans-enoyl)oxazolidin-2-ones, as derivatives of an α,β-unsaturated carboxylic acid, were found to be the substrates of choice featuring geometric/conformational homogeneity and high reactivity. The corresponding Michael addition reactions were found to proceed at room temperature in the presence of catalytic amounts of DBU to afford quantitatively the addition products with virtually complete diastereoselectivity. Acidic decomposition of the products followed by treatment of the reaction mixture with NH4OH gave rise to the diastereomerically pure 3-substituted pyroglutamic acids.
