亚硝胺效力的量子力学评估

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-05-28 DOI:10.1021/acs.chemrestox.4c00087
Sriman De, Bishnu Thapa, Fareed Bhasha Sayyed*, Scott A. Frank, Paul D. Cornwell and Robert A. Jolly*, 
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引用次数: 0

摘要

亚硝胺属于监管指南确定的关注群组 (CoC)。CoC 化合物被认为是强致癌物,需要限制在毒理学阈值(1.5 微克/天)以下。亚硝胺(如 NDMA 和 NDEA)需要严格控制,而新型亚硝胺药物物质相关杂质(NDSRIs)可能会也可能不会被定性为强致癌物。由于 NDSRIs 缺乏特定物质的致癌性,因此基于 NDSRIs 结构特征的风险评估对于预测其毒性非常重要。在此,我们介绍了基于量子力学(QM)的亚硝胺结构多样性分析,以更好地了解结构如何影响可能导致致癌的反应性。我们通过与 α-羟化、醛形成、重氮中间体形成、与 DNA 碱反应、水解反应以及与亚硝胺致癌性相关的其他可能代谢途径相对应的活化能来描述其效力趋势。我们评估了某些情况下的活化能,如 N-亚硝基吡咯烷、N-亚硝基哌啶、N-亚硝基哌嗪、N-亚硝基吗啉、N-亚硝基硫代吗啉、N-甲基亚硝基芳香族、氟取代亚硝胺和取代脂肪族亚硝胺。我们将这些结果与卫生当局最近提出的致癌性表征方法 (CPCA) 框架进行了比较,该框架旨在为缺乏特定物质致癌性数据的 NDSRIs 的可接受摄入量 (AI) 提供指导。我们举例说明了质量管理建模与 CPCA 相吻合的情况,以及 CPCA 低估和高估可接受摄入量的情况。在 CPCA 预测 NDSRIs 具有高药效的情况下,QM 模型可以帮助更好地估计 AI。我们的研究结果表明,结合对 α-羟化、醛形成、水解以及与 DNA 碱基反应的机理理解,有助于确定亚硝胺药效的结构特征。我们预计这项工作将是对 CPCA 的宝贵补充,并为估算新型 NDSRIs 的 AI 提供了一种更具分析性的方法。
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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Quantum Mechanical Assessment of Nitrosamine Potency

Nitrosamines are in the cohort of concern (CoC) as determined by regulatory guidance. CoC compounds are considered highly potent carcinogens that need to be limited below the threshold of toxicological concern, 1.5 μg/day. Nitrosamines like NDMA and NDEA require strict control, while novel nitrosamine drug substance-related impurities (NDSRIs) may or may not be characterized as potent carcinogens. A risk assessment based on the structural features of NDSRIs is important in order to predict potency because they lack substance-specific carcinogenicity. Herein, we present a quantum mechanical (QM)-based analysis on structurally diverse sets of nitrosamines to better understand how structure influences the reactivity that could result in carcinogenicity. We describe the potency trend through activation energies corresponding to α-hydroxylation, aldehyde formation, diazonium intermediate formation, reaction with DNA base, and hydrolysis reactions, and other probable metabolic pathways associated with the carcinogenicity of nitrosamines. We evaluated activation energies for selected cases such as N-nitroso pyrrolidines, N-nitroso piperidines, N-nitroso piperazines, N-nitroso morpholines, N-nitroso thiomorpholine, N-methyl nitroso aromatic, fluorine-substituted nitrosamines, and substituted aliphatic nitrosamines. We compare these results to the recent framework of the carcinogenic potency characterization approach (CPCA) proposed by health authorities which is meant to give guidance on acceptable intakes (AI) for NDSRIs lacking substance-specific carcinogenicity data. We show examples where QM modeling and CPCA are aligned and examples where CPCA both underestimates and overestimates the AI. In cases where CPCA predicts high potency for NDSRIs, QM modeling can help better estimate an AI. Our results suggest that a combined mechanistic understanding of α-hydroxylation, aldehyde formation, hydrolysis, and reaction with DNA bases could help identify the structural features that underpin the potency of nitrosamines. We anticipate this work will be a valuable addition to the CPCA and provide a more analytical way to estimate AI for novel NDSRIs.

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567
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