126158-10-9Relevant articles and documents
Iridium-catalyzed highly chemoselective and efficient reduction of nitroalkenes to nitroalkanes in water
Chen, Yang,Liu, Changmeng,Xu, Dong,Xu, Jiaxi,Yang, Zhanhui
supporting information, p. 6050 - 6058 (2021/08/23)
An iridium-catalyzed highly chemoselective and efficient transfer hydrogenation reduction of structurally diverse nitroalkenes was realized at very low catalyst loading (S/C = up to 10000 or 20?000), using formic acid or sodium formate as a traceless hydride donor in water. Excellent functionality tolerance is also observed. The turnover number and turnover frequency of the catalyst reach as high as 18?600 and 19?200 h-1, respectively. An inert atmosphere protection is not required. The reactivities of nitroalkenes are dependent on their substitution pattern, and the pH value is a key factor to accomplish the complete conversion and excellent chemoselectivity. Purification of products is achieved by simple extraction without column chromatography. The reduction procedure is facilely amplified to 10 g scale at 10?000 S/C ratio. The potential of this green reduction in enantioselective hydrogenation has been demonstrated.
Increasing C-Terminal Hydrophobicity Improves the Cell Permeability and Antiproliferative Activity of PACE4 Inhibitors against Prostate Cancer Cell Lines
Dianati, Vahid,Kwiatkowska, Anna,Couture, Frédéric,Desjardins, Roxane,Dory, Yves L.,Day, Robert
, p. 8457 - 8467 (2018/09/27)
The serine protease, PACE4, is a proprotein convertase that plays a substantial role in malignancy of prostate cancer. Our initial selective PACE4 inhibitor (Ac-LLLLRVKR-NH2) has evolved to the current lead compound C23 (Ac-dLeu-LLLRVK-Amba), w
New approach to oximes through reduction of nitro compounds enabled by visible light photoredox catalysis
Cai, Shunyou,Zhang, Shaolong,Zhao, Yaohong,Wang, David Zhigang
, p. 2660 - 2663 (2013/07/11)
A range of nitro compounds are smoothly reduced to their corresponding oximes under the synergistic effects of visible light irradiation, the Ru(bpy)3Cl2 photocatalyst, Hünig's base, Mg(ClO 4)2 activation, and MeCN solvent. This remarkably mild and environmentally benign protocol, when orchestrated with classical Beckmann rearrangement, enables such high-value industrial feedstock as caprolactam to be readily accessed from simple precursor nitrocyclohexane.