In silico Studies of Cilnidipine Degradation Products for Structure Confirmation, Toxicity Prediction and Molecular Docking

Q4 Chemistry

Asian Journal of Chemistry Pub Date : 2024-03-30 DOI:10.14233/ajchem.2024.31150

Krishnam Raju Chintalapati, Yesudas Kada, Vasavi Malkhed, Sanath Kumar Goud Palusa, Rabin Bera, V. S. K. Jagarlapudi

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Abstract

In this study, a comprehensive analysis of cilnidipine and its degradation products (KD1-KD4 and CD1-CD3) with three main objectives viz. (i) toxicity prediction for bacterial mutagenicity, (ii) assessment of pharmacological activity and (iii) density functional theory (DFT) calculations were performed for structure confirmation. For bacterial mutagenicity prediction, in silico assessments were performed following ICH M7 guidelines. Using rule-based and statistical-based methodologies, predictions revealed an alerting group in CD1-CD3, while no alerting group was observed in KD1-KD4 for bacterial mutagenicity. To assess pharmacological activity, docking studies were conducted to identify the mode of binding and interaction types of cilnidipine and its degradation products with N-type and L-type calcium channel subunits 7VFS and 7UHF, respectively. Additionally, 20 drugs acting as calcium channel blockers were considered for docking analysis to correlate the affinities of binding. The interaction energies revealed that molecule CD3 shows the highest binding affinity with the ligand molecules, with a binding energy of -9.2 (kcal/mol) with 7VFS and -8.7 (kcal/mol) with 7UHF proteins, followed by KD3 with a binding energy of -8.7 (kcal/mol) (7VFS) and -7.9 (kcal/mol) (7UHF). Furthermore, DFT calculations were employed to reassess the structures of degradation products CD1 and CD2 proposed in the literature. Simulating 1H and 13C NMR spectra, the obtained data demonstrated good agreement with experimental results, confirming the proposed stereo-configurations in the literature. Based on in silico bacterial mutagenicity predictions and docking studies, KD3 emerged as a promising compound for receptor binding. Additionally, DFT calculations provided structural insights, affirming stereo-configurations proposed in the existing literature. This multifaceted approach contributed valuable insights into the toxicity, pharmacology and structural aspects of cilnidipine degradation products.

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用于结构确认、毒性预测和分子对接的西尼地平降解产物的硅学研究

本研究对西尼地平及其降解产物（KD1-KD4 和 CD1-CD3）进行了全面分析，主要有三个目标，即：(i) 细菌致突变毒性预测；(ii) 药理活性评估；(iii) 用于结构确认的密度泛函理论（DFT）计算。在细菌诱变性预测方面，按照 ICH M7 准则进行了硅学评估。利用基于规则和统计的方法，预测结果显示 CD1-CD3 中存在警戒群，而 KD1-KD4 中未发现细菌诱变性警戒群。为评估药理活性，进行了对接研究，以确定西尼地平及其降解产物分别与 N 型和 L 型钙通道亚基 7VFS 和 7UHF 的结合模式和相互作用类型。此外，还考虑了 20 种作为钙通道阻滞剂的药物进行对接分析，以确定其结合亲和力。相互作用能显示，CD3分子与配体分子的结合亲和力最高，与7VFS蛋白的结合能为-9.2（kcal/mol），与7UHF蛋白的结合能为-8.7（kcal/mol）；其次是KD3，与7VFS蛋白的结合能为-8.7（kcal/mol），与7UHF蛋白的结合能为-7.9（kcal/mol）。此外，还利用 DFT 计算重新评估了文献中提出的降解产物 CD1 和 CD2 的结构。模拟 1H 和 13C NMR 光谱得到的数据与实验结果非常吻合，证实了文献中提出的立体构型。根据硅学细菌诱变性预测和对接研究，KD3 成为有希望与受体结合的化合物。此外，DFT 计算提供了结构见解，肯定了现有文献中提出的立体构型。这种多方面的研究方法有助于深入了解西尼地平降解产物的毒性、药理和结构。

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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