Identification of a 2-aminothiazole framework using classical QSAR model targeting chloroquine-sensitive Plasmodium falciparum

International Journal of Research in Pharmaceutical Sciences Pub Date : 2024-02-06 DOI:10.26452/ijrps.v15i1.4659

Ravindran Karuppaiyan, Anitha Gunavel, Kasthuri Bai Solai, Prabha Thangavelu

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Abstract

Chloroquine-sensitive Plasmodium falciparum is the most deadly form of human malaria. It is associated with a number of mutations in P. falciparum. Chloroquine-resistant transporter is a protein that serves as a transporter in the parasite's digesting vacuole membrane. In order to combat chloroquine-sensitive P. falciparum strains (NF54), this study employs QSAR modelling to examine possible structural alterations of 2-amino-thiazole derivatives. The traditional QSAR model was built using the PaDEL descriptor via QSARINS software. The model was found to have an internal cross-validation value of Q2loo = 0.7890 and an external validation parameter of RMSE ext = 0.6938. The predicted pIC50 values from the QSAR techniques for the case study chemicals were compared and found to be well fitted to the model and well predicted for the external set of compounds. The outcome demonstrates the value of using the suggested method in the creation of new medication candidates could fill the critical gap in scientific knowledge and open up novel possibilities for pharmaceutical development.

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利用经典 QSAR 模型鉴定针对氯喹敏感恶性疟原虫的 2-氨基噻唑框架

对氯喹敏感的恶性疟原虫是人类疟疾中最致命的一种。它与恶性疟原虫的一些突变有关。耐氯喹转运体是寄生虫消化泡膜上的一种转运蛋白。为了对付对氯喹敏感的恶性疟原虫菌株（NF54），本研究采用 QSAR 模型来研究 2-氨基噻唑衍生物可能发生的结构变化。传统的 QSAR 模型是通过 QSARINS 软件使用 PaDEL 描述符建立的。该模型的内部交叉验证值为 Q2loo = 0.7890，外部验证参数 RMSE ext = 0.6938。比较了 QSAR 技术对案例研究化学品的 pIC50 预测值，发现模型拟合良好，对外部化合物集的预测也很准确。结果表明，使用所建议的方法创造新的候选药物具有重要价值，可以填补科学知识方面的关键空白，并为药物开发开辟新的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Research in Pharmaceutical Sciences

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