17449-76-2Relevant articles and documents
Trans-Selective and Switchable Arene Hydrogenation of Phenol Derivatives
Bergander, Klaus,Glorius, Frank,Heusler, Arne,Wollenburg, Marco
, p. 11365 - 11370 (2020/11/24)
A trans-selective arene hydrogenation of abundant phenol derivatives catalyzed by a commercially available heterogeneous palladium catalyst is reported. The described method tolerates a variety of functional groups and provides access to a broad scope of trans-configurated cyclohexanols as potential building blocks for life sciences and beyond in a one-step procedure. The transformation is strategically important because arene hydrogenation preferentially delivers the opposite cis-isomers. The diastereoselectivity of the phenol hydrogenation can be switched to the cis-isomers by employing rhodium-based catalysts. Moreover, a protocol for the chemoselective hydrogenation of phenols to cyclohexanones was developed.
FACTOR XIA-INHIBITING PYRIDOBENZAZEPINE AND PYRIDOBENZAZOCINE DERIVATIVES
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Paragraph 0772-0774, (2017/10/10)
The invention relates to substituted pyridobenzazepine and pyridobenzazocine derivatives and to processes for preparation thereof, and also to the use thereof for production of medicaments for treatment and/or prophylaxis of diseases, especially of cardiovascular disorders, preferably thrombotic or thromboembolic disorders, and oedemas, and also ophthalmic disorders.
A nitric oxide-dexamethasone and preparation method and use thereof
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Paragraph 0045; 0046, (2017/01/17)
The invention relates to nitric oxide donor type hexadecadrol as well as a preparation method and application thereof. The nitric oxide donor type hexadecadrol as a compound is obtained by enabling nitrous acid ester to be connected with hexadecadrol through ethyl cyclohexanecarboxylate; the in-vitro antiinflammatory activity of the nitric oxide donor type hexadecadrol is better than that of the hexadecadrol; besides, the nitric oxide donor type hexadecadrol can restrain the growth of methicillin-resistant staphylococcus aureus (MRSA) in vitro, restrain the formation of MRSA biomembrane, and lead to the death of bacteria in the MRSA biomembrane. In addition, the compound can notably increase the survival rate of mice in MRSA sepsis lethal models, reduces the inflammation pathology damage of the mice in sub-sepsis models, decreases the constant value number of bacteria, and has notable advantages in the respect of preventing and treating MRSA sepsis.