3550-21-8Relevant articles and documents
Pharmacological characterization of a new series of carbamoylguanidines reveals potent agonism at the H2R and D3R
Biselli, Sabrina,Bresinsky, Merlin,Buschauer, Armin,Forster, Lisa,Honisch, Claudia,Pockes, Steffen,Tropmann, Katharina,Bernhardt, Günther
supporting information, (2021/02/12)
Even today, the role of the histamine H2 receptor (H2R) in the central nervous system (CNS) is widely unknown. In previous research, many dimeric, high-affinity and subtype-selective carbamoylguanidine-type ligands such as UR-NK22 (5, pKi = 8.07) were reported as H2R agonists. However, their applicability to the study of the H2R in the CNS is compromised by their molecular and pharmacokinetic properties, such as high molecular weight and, consequently, a limited bioavailability. To address the need for more drug-like H2R agonists with high affinity, we synthesized a series of monomeric (thio)carbamoylguanidine-type ligands containing various spacers and side-chain moieties. This structural simplification resulted in potent (partial) agonists (guinea pig right atrium, [35S]GTPγS and β-arrestin2 recruitment assays) with human (h) H2R affinities in the one-digit nanomolar range (pKi (139, UR-KAT523): 8.35; pKi (157, UR-MB-69): 8.69). Most of the compounds presented here exhibited an excellent selectivity profile towards the hH2R, e.g. 157 being at least 3800-fold selective within the histamine receptor family. The structural similarities of our monomeric ligands to pramipexole (6), a dopamine receptor agonist, suggested an investigation of the binding behavior at those receptors. The target compounds were (partial) agonists with moderate affinity at the hD2longR and agonists with high affinity at the hD3R (e.g. pKi (139, UR-KAT523): 7.80; pKi (157, UR-MB-69): 8.06). In summary, we developed a series of novel, more drug-like H2R and D3R agonists for the application in recombinant systems in which either the H2R or the D3R is solely expressed. Furthermore, our ligands are promising lead compounds in the development of selective H2R agonists for future in vivo studies or experiments utilizing primary tissue to unravel the role and function of the H2R in the CNS.
Synthesis methods for isothiocyanate derivative
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Paragraph 0033; 0034; 0035; 0036; 0109; 0110; 0111; 0112, (2019/05/22)
The invention discloses synthesis methods for an isothiocyanate derivative. The first synthesis method includes reacting raw materials, including primary amine, trifluoromethyltrimethylsilane, potassium fluoride and sulfur, with an organic solvent at the room temperature to obtain the isothiocyanate derivative. The synthetic isothiocyanate derivative has the advantages of simple operation, safety,high efficiency, non-toxicity, low raw material price, mild condition, high yield, wide application range of substrates, high compatibility of functional groups and the like. The second synthesis method includes reacting raw materials, including the primary amine, silver trifluoromethane and potassium bromide, with the organic solvent at the room temperature to obtain the isothiocyanate derivative. The isothiocyanate derivative has the advantages of simple operation, safety, high efficiency, easy availability of the raw materials, nearly quantitative yield, wide application range of the substrates, applicability to selective post-modification of drugs or complex compounds, and the like.
Systematic structure-activity relationship (SAR) exploration of diarylmethane backbone and discovery of a highly potent novel uric acid transporter 1 (URAT1) inhibitor
Cai, Wenqing,Wu, Jingwei,Liu, Wei,Xie, Yafei,Liu, Yuqiang,Zhang, Shuo,Xu, Weiren,Tang, Lida,Wang, Jianwu,Zhao, Guilong
, (2018/02/07)
In order to systematically explore and better understand the structure-activity relationship (SAR) of a diarylmethane backbone in the design of potent uric acid transporter 1 (URAT1) inhibitors, 33 compounds (1a-1x and 1ha-1hi) were designed and synthesized, and their in vitro URAT1 inhibitory activities (IC50) were determined. The three-round systematic SAR exploration led to the discovery of a highly potent novel URAT1 inhibitor, 1h, which was 200-and 8-fold more potent than parent lesinurad and benzbromarone, respectively (IC50 = 0.035 μM against human URAT1 for 1h vs. 7.18 μM and 0.28 μM for lesinurad and benzbromarone, respectively). Compound 1h is the most potent URAT1 inhibitor discovered in our laboratories so far and also comparable to the most potent ones currently under development in clinical trials. The present study demonstrates that the diarylmethane backbone represents a very promising molecular scaffold for the design of potent URAT1 inhibitors.