39595-88-5Relevant academic research and scientific papers
Benzo aza compound, preparation method and use thereof
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, (2017/08/22)
Belonging to the field of pharmaceutical chemistry, the invention relates to a benzoazepine compound, a preparation method and application thereof, in particular to the benzoazepine compound, its preparation method and application in the field of treatment of nervous system diseases, especially application in the field of drug addiction related to dopamine D1 and D3 receptors. The benzoazepine compound and pharmacologically acceptable inorganic or organic salts thereof have a structure shown as formula (I). Results of drug experiments carried out by the invention show that the benzoazepine compound and its pharmacologically acceptable inorganic or organic salts have high antagonistic activity on dopamine D1 and D3, can be used as drug leads for further development of dopamine receptor antagonists with good selectivity and high activity, and can be used as potential drugs for treatment of drug addiction by dopamine D1, D3 receptor antagonists. (formula (I)).
Functional reversal of (?)-Stepholidine analogues by replacement of benzazepine substructure using the ring-expansion strategy
Li, Wei,Zhang, Li,Xu, Lili,Yuan, Congmin,Du, Peng,Chen, Jiaojiao,Zhen, Xuechu,Fu, Wei
, p. 599 - 607 (2016/10/06)
(?)-Stepholidine is an active ingredient of the Chinese herb Stephania and naturally occurring tetrahydroprotoberberine alkaloid with mixed dopamine receptor D1 agonistic and dopamine receptor D2 antagonistic activities. In this work, a series of novel hexahydrobenzo[4,5]azepino [2,1-a]isoquinolines were designed and synthesized as ring-expanded analogues of (?)-Stepholidine. Initial pharmacological assays demonstrated that a benzazepine replacement was associated with significant increase in selectivity and functional reversal at dopamine receptor D1. Compound-(?)-15e (Ki?=?5.32?±?0.01?nm) is more potent than (?)-Stepholidine (Ki?=?13?nm) and was identified as a selective dopamine receptor D1 antagonist (IC50?=?0.14?μm). Moreover, molecular modeling suggested that (?)-15e might exert its dopamine receptor D1 antagonistic activities through interacting with the transmembrane helix 7 of dopamine receptor D1.
Highly convergent total synthesis of (+)-lithospermic acid via a late-stage intermolecular C-H olefination
Wang, Dong-Hui,Yu, Jin-Quan
supporting information; experimental part, p. 5767 - 5769 (2011/06/22)
The total synthesis of (+)-lithospermic acid is reported, which exploits two successive C-H activation reactions as key steps. Rh-catalyzed carbene C-H insertion reaction utilizing Davies's catalyst was used to forge dihydrobenzofuran core, and a late-sta
Design, synthesis, structure-activity relationships, and biological characterization of novel arylalkoxyphenylalkylamine σ ligands as potential antipsychotic drugs
Nakazato, Atsuro,Ohta, Kohmei,Sekiguchi, Yoshinori,Okuyama, Shigeru,Chaki, Shigeyuki,Kawashima, Yutaka,Hatayama, Katsuo
, p. 1076 - 1087 (2007/10/03)
Receptor antagonists may be effective antipsychotic drugs that do not induce motor side effects caused by ingestion of classical drugs such as haloperidol. We obtained evidence that 1-(2-dipropylaminoethyl)-4-methoxy- 6H-dibenzo[b,d]pyran hydrochloride 2a had selective affinity for σ receptor over dopamine D2 receptor. This compound was designed to eliminate two bonds of apomorphine 1 to produce structural flexibility for the nitrogen atom and to bridge two benzene rings with a -CH2O- bond to maintain the planar structure. In light of the evidence, N,Y-dipropyl-2-(4-methoxy-3- benzyloxylphenyl)ethylamine hydrochloride 10b was designed. Since compound 10b had eliminated a biphenyl bond of 6H-dibenzo[b,d]pyran derivative 2a, it might be more released from the rigid structure of apomorphine 1 than compound 2a. The chemical modification of compound 10b led to the discovery that N,N-dipropyl-2-[4-methoxy-3-(2-phenylethoxyl)phenyl]ethylamine hydrochloride 10g (NE- 100), the best compound among arylalkoxyphenylalkylamine derivatives 3, had a high and selective affinity for σ receptor and had a potent activity in an animal model when the drug was given orally. We report here the design, synthesis, structure-activity relationships, and biological characterization of novel arylalkoxyphenylalkylamine derivatives 3.
