142-26-7Relevant articles and documents
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Nefedov et al.
, (1974)
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Safe synthesis of alkylhydroxy and alkylamino nitramines
Antonsen, Simen,Aursnes, Marius,Gallantree-Smith, Harrison,Dye, Christian,Stenstr?m, Yngve
, (2016)
Three different protocols for the syntheses of hydroxyalkylnitramines are presented and compared. Safety issues regarding the synthesis of nitramines are also discussed.
Switching Lysophosphatidylserine G Protein-Coupled Receptor Agonists to Antagonists by Acylation of the Hydrophilic Serine Amine
Sayama, Misa,Uwamizu, Akiharu,Ikubo, Masaya,Chen, Luying,Yan, Ge,Otani, Yuko,Inoue, Asuka,Aoki, Junken,Ohwada, Tomohiko
, p. 10059 - 10101 (2021/07/28)
Three human G protein-coupled receptors (GPCRs)—GPR34/LPS1, P2Y10/LPS2, and GPR174/LPS3—are activated specifically by lysophosphatidylserine (LysoPS), an endogenous hydrolysis product of a cell membrane component, phosphatidylserine (PS). LysoPS consists of-serine, glycerol, and fatty acid moieties connected by phosphodiester and ester linkages. We previously generated potent and selective GPCR agonists by modification of the three modules and the ester linkage. Here, we show that a novel modification of the hydrophilic serine moiety, that is, N-acylations of the serine amine, converted a GPR174 agonist to potent GPR174 antagonists. Structural exploration of the amide functionality provided access to a range of activities from agonist to partial agonist to antagonist. The present study would provide a new strategy for the development of lysophospholipid receptor antagonists.
Method for preparing 3-ketomorpholine
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Paragraph 0062-0064, (2019/03/26)
The invention relates to a method for preparing 3-ketomorpholine. The method comprises the following steps: protecting the amino group of ethanolamine firstly, then carrying out a reaction of amino group protected ethanolamine with alkyl haloacetate, performing deprotection on the prepared product, and performing ring closure so as to obtain 3-ketomorpholine. The method has the advantages of simple practical operation, low equipment requirements, high yield and low three waste, and is suitable for industrial large-scale production.
Formation of carbon–nitrogen bonds in carbon monoxide electrolysis
Jouny, Matthew,Lv, Jing-Jing,Cheng, Tao,Ko, Byung Hee,Zhu, Jun-Jie,Goddard, William A.,Jiao, Feng
, p. 846 - 851 (2019/09/03)
The electroreduction of CO2 is a promising technology for carbon utilization. Although electrolysis of CO2 or CO2-derived CO can generate important industrial multicarbon feedstocks such as ethylene, ethanol, n-propanol and acetate, most efforts have been devoted to promoting C–C bond formation. Here, we demonstrate that C–N bonds can be formed through co-electrolysis of CO and NH3 with acetamide selectivity of nearly 40% at industrially relevant reaction rates. Full-solvent quantum mechanical calculations show that acetamide forms through nucleophilic addition of NH3 to a surface-bound ketene intermediate, a step that is in competition with OH– addition, which leads to acetate. The C–N formation mechanism was successfully extended to a series of amide products through amine nucleophilic attack on the ketene intermediate. This strategy enables us to form carbon–heteroatom bonds through the electroreduction of CO, expanding the scope of products available from CO2 reduction.