140695-84-7Relevant articles and documents
An efficient synthesis of 3(S)-aminopiperidine-5(R)-carboxylic acid as a cyclic β,γ′-diamino acid
Park, Jin-Seong,Yeom, Chang-Eun,Choi, Soo Hyuk,Ahn, Yong Shik,Ro, Sunggu,Jeon, Young Ho,Shin, Dong-Kyu,Kim, B. Moon
, p. 1611 - 1614 (2003)
An orthogonally protected β,γ′-diamino acid 6 possessing conformationally-constrained ring system was synthesized as a novel cyclic amino acid analogue. This synthesis involves as key steps chemoselective enzymatic hydrolysis of cis-piperidine-3,5-dicarboxylic ester derivative followed by efficient kinetic resolution of the partially resolved half-acid to afford the C1-symmetric piperidine-3,5-dicarboxylic acid monoester in high enantiomeric excess (>98% ee). The optically active half-acid was transformed to the cyclic amino acid via Curtius-type rearrangement.
Discovery of 3-amino-4-{(3S)-3-[(2-ethoxyethoxy)methyl]piperidin-1-yl}thieno[2,3-b]pyridine-2-carboxamide (DS96432529): A potent and orally active bone anabolic agent
Kunikata, Tomonori,Nagai, Yoko,Naito, Satoru,Nakai, Daisuke,Nakao, Akira,Saito, Keiji,Shinozuka, Tsuyoshi
supporting information, (2021/11/20)
The continuing investigation of SAR of 3-aminothieno[2,3-b]pyridine-2-carboxamide derivatives has been described. In this study, C4-piperidine derivatives with polar functional groups were synthesized to develop orally available bone anabolic agents. The optimized compound 9o (DS96432529), which exhibited the best PK profile and high in vitro activity, showed the highest in vivo efficacy in this series. Moreover, significant synergistic effects were observed following co-administration of DS96432529 and alendronate or parathyroid hormone. The mechanism of action is most likely mediated through CDK8 inhibition.
Palladium-catalyzed ring-closing reaction via C-N bond metathesis for rapid construction of saturated N-heterocycles
Yu, Bangkui,Zou, Suchen,Liu, Hongchi,Huang, Hanmin
, p. 18341 - 18345 (2020/11/17)
The ring-closing reactions based on chemical bond metathesis enable the efficient construction of a wide variety of cyclic systems which receive broad interest from medicinal and organic communities. However, the analogous reaction with C-N bond metathesis as a strategic fundamental step remains an unanswered challenge. Herein, we report the design of a new fundamental metallic C-N bond metathesis reaction that enables the palladium-catalyzed ring-closing reaction of aminodienes with aminals. The reactions proceed efficiently under mild conditions and exhibit broad substrate generality and functional group compatibility, leading to a wide variety of 5- to 16-membered N-heterocycles bearing diverse frameworks and functional groups.