51073-69-9Relevant articles and documents
NOVEL CELL METABOLISM MODULATING COMPOUNDS AND USES THEREOF
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Page/Page column 214-215; 254-255, (2021/07/31)
A class of compounds that bind to fatty acid binding protein (FABP4) and modulate adipocyte metabolism to drive enhanced glucose utilization, as well as pharmaceutical compositions comprising the class of compounds, in combination with a pharmaceutically acceptable diluent or carrier, and optionally, further in combination with a therapeutically active agent, and the use of these compounds in medicine and for the preparation of a medicament in the treatment of disorders acting on the FABP4.
Deoxygenative Arylation of Carboxylic Acids by Aryl Migration
Ruzi, Rehanguli,Ma, Junyang,Yuan, Xiang-Ai,Wang, Wenliang,Wang, Shanshan,Zhang, Muliang,Dai, Jie,Xie, Jin,Zhu, Chengjian
, p. 12724 - 12729 (2019/11/05)
An unprecedented deoxygenative arylation of aromatic carboxylic acids has been achieved, allowing the construction of an enhanced library of unsymmetrical diaryl ketones. The synergistic photoredox catalysis and phosphoranyl radical chemistry allows for precise cleavage of a stronger C?O bond and formation of a weaker C?C bond by 1,5-aryl migration under mild reaction conditions. This new protocol is independent of substrate redox-potential, electronic, and substituent effects. It affords a general and promising access to 60 examples of synthetically versatile o-amino and o-hydroxy diaryl ketones under redox-neutral conditions. Furthermore, it also brings one concise route to the total synthesis of quinolone alkaloid, (±)-yaequinolone A2, and a viridicatin derivative in satisfying yields.
Synthesis of 3-Substituted 2,1-Benzisoxazoles by the Oxidative Cyclization of 2-Aminoacylbenzenes with Oxone
Chiarini, Marco,Del Vecchio, Luana,Marinelli, Fabio,Rossi, Leucio,Arcadi, Antonio
, p. 3017 - 3030 (2016/10/12)
An efficient approach to the synthesis of 2,1-benzisoxazoles through direct construction of the N-O bond by the chemoselective oxidation of 2-aminoacylbenzenes with Oxone is described. This alternative methodology is characterized by its simple and transition-metal-free conditions and good functional group compatibility utilizing Oxone as a green oxidant instead of hypervalent iodine compounds. Moreover, this new procedure simplifies the number of steps compared to the previously reported procedure by circumventing the use of 2-azido-substituted aryl ketones.