噻唑烷-4-酮类似物:合成、硅内分子建模和体内抗惊厥潜力评估。

Payal Mittal, Deepak Ghanghas, Diksha Sharma, Kamal Shah, Girish Chandra Arya, Aarti Chaudhary, Hitesh Kumar Dewangan
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引用次数: 0

摘要

背景:癫痫是一种根深蒂固的中枢神经系统疾病,影响着全球 5000 多万人。因此,迫切需要一种安全有效的治疗方法来证明其在治疗这种疾病方面的价值。噻唑烷-4-酮具有可用作抗惊厥药的分子。噻唑烷二酮是硫代氨基脲类和硫脲类的环状类似物,也是海因(咪唑烷-2,4-二酮)的(生物)异构体,是公认的新型抗惊厥药物:方法:采用三组份缩合法配制新型噻唑烷-4-酮衍生物。发现所选的 OH(醇)衍生物更有效,因此针对所选的目标 LGI1 LRR 结构域进行了分子对接研究。傅立叶变换红外光谱和 H1 NMR 等各种分析测试均已完成。傅立叶变换红外光谱用于验证在 3075 cm-1 - 1236 cm-1 波段是否存在多种功能分子,如 C-S、O-H、C=O、C-N、N=O、C-NH、C-O;H1 NMR 用于确定合成的类似物是否具有完整的质子集。然后,用小鼠 PTZ 模型检测了所选化合物在 25、50 和 100 毫克/千克三个连续剂量下的抗癫痫活性,并与标准乙琥胺进行了比较:在确定受体和配体的结合位点并适当制备后,使用 PyMOL 进行了对接模拟。与市场上的标准药物乙琥胺相比,该药物显示出更高的结合频率。傅立叶变换红外光谱和 H1 NMR 光谱用于表征化学成分。在合成的分子中可以看到许多官能团,包括 O-H(醇)、C=O(酮)、N=O、C-NH、C-N、C-S 和 C-O 弯曲伸展。在 100 毫克/千克的浓度下,合成的化合物能有效抑制抽搐:结论:新型噻唑烷-4-酮衍生物显示出良好的活性,可考虑用于进一步研究和制备剂型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thiazolidine-4-one Analogues: Synthesis, In-Silico Molecular Modeling, and In-vivo Estimation for Anticonvulsant Potential.

Background: Epilepsy is a critically deep-rooted CNS disorder affecting above 50 million people all over the world. Thus, a safe and effective treatment that proves its worth in this ailment is urgently needed. Thiazolidine-4-ones possess the molecules to be used as anticonvulsants. The thiazolidinedione is a cyclic analogue of thiosemicarbazides and thioureas as well as a (bio)isostere of hydantoin (imidazolidine-2,4-dione), which are recognized as novel anticonvulsant designs.

Aim: This study aimed to develop and evaluate a novel thiazolidine-4-one derivative by three-component condensation in one pot reaction method.

Methods: A novel thiazolidine-4-one derivative was formulated by three-component condensation. The selected OH (Alcohol) derivatives were found to be more potent; hence, a molecular docking study against a selected target LGI1 LRR domain was performed. Various analytical tests like FTIR and H1 NMR were accomplished. The FTIR was used to validate the existence of multiple functional moieties like C-S, O-H, C=O, C-N, N=O, C-NH, C-O in the wave region from 3075 cm-1 - 1236 cm-1 and H1 NMR was employed to ascertain if the synthesized analogues had the complete set of protons. Then, the anti-seizure activity of the selected compound was examined using PTZ models in mice at three successive doses, i.e., 25, 50, and 100mg/kg, and compared with standard ethosuximide.

Results: The docking simulations were initiated using PyMOL after the binding site was determined and the receptor and ligand were suitably prepared. It showed higher binding frequency in comparison to the standard marketed drug Ethosuximide. FTIR and H1 NMR spectroscopy were used to characterize the chemical components. Numerous functional groups, including O-H (alcohol), C=O (ketones), N=O, C-NH, C-N, C-S, and C-O bending stretching, were visible in the synthesized molecule accordingly. The synthesized compound was effective in inhibiting the convulsions at the concentration of 100 mg/kg.

Conclusion: The novel thiazolidine-4-one derivative showed promising activity and could be considered for further investigation and dosage form preparation.

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