In Silico Prediction of N-Nitrosamine Formation Pathways of Pharmaceutical Products

IF 1.5 4区医学 Q4 CHEMISTRY, MEDICINAL

Chemical & pharmaceutical bulletin Pub Date : 2024-02-01 DOI:10.1248/cpb.c23-00550

Genichiro Tsuji, Takashi Kurohara, Takuji Shoda, Hidetomo Yokoo, Takahito Ito, Sayaka Masada, Nahoko Uchiyama, Eiichi Yamamoto, Yosuke Demizu

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Abstract

The recent discovery of N-nitrosodimethylamine (NDMA), a mutagenic N-nitrosamine, in pharmaceuticals has adversely impacted the global supply of relevant pharmaceutical products. Contamination by N-nitrosamines diverts resources and time from research and development or pharmaceutical production, representing a bottleneck in drug development. Therefore, predicting the risk of N-nitrosamine contamination is an important step in preventing pharmaceutical contamination by DNA-reactive impurities for the production of high-quality pharmaceuticals. In this study, we first predicted the degradation pathways and impurities of model pharmaceuticals, namely gliclazide and indapamide, in silico using an expert-knowledge software. Second, we verified the prediction results with a demonstration test, which confirmed that N-nitrosamines formed from the degradation of gliclazide and indapamide in the presence of hydrogen peroxide, especially under alkaline conditions. Furthermore, the pathways by which degradation products formed were determined using ranitidine, a compound previously demonstrated to generate NDMA. The prediction indicated that a ranitidine-related compound served as a potential source of nitroso groups for NDMA formation. In silico software is expected to be useful for developing methods to assess the risk of N-nitrosamine formation from pharmaceuticals.

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医药产品中 N-亚硝胺形成途径的硅学预测

最近在药品中发现的 N-亚硝基二甲胺（NDMA）是一种致突变的 N-亚硝胺，对全球相关药品的供应产生了不利影响。N-nitrosamines 污染占用了研发或药品生产的资源和时间，成为药物开发的瓶颈。因此，预测 N-亚硝胺污染的风险是防止 DNA 反应杂质污染药品以生产高质量药品的重要一步。在本研究中，我们首先利用专家知识软件对格列齐特和吲达帕胺这两种模型药物的降解途径和杂质进行了硅学预测。其次，我们通过演示试验验证了预测结果，证实格列齐特和吲达帕胺在过氧化氢存在下，特别是在碱性条件下降解会形成 N-亚硝胺。此外，还利用雷尼替丁确定了降解产物形成的途径，雷尼替丁是一种先前被证明会产生 NDMA 的化合物。预测结果表明，雷尼替丁相关化合物是 NDMA 形成的亚硝基的潜在来源。预计硅学软件将有助于开发评估药品中 N-亚硝胺形成风险的方法。

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来源期刊

Chemical & pharmaceutical bulletin 医学-化学综合

CiteScore

3.20

自引率

5.90%

发文量

132

审稿时长

1.7 months

期刊介绍： The CPB covers various chemical topics in the pharmaceutical and health sciences fields dealing with biologically active compounds, natural products, and medicines, while BPB deals with a wide range of biological topics in the pharmaceutical and health sciences fields including scientific research from basic to clinical studies. For details of their respective scopes, please refer to the submission topic categories below. Topics: Organic chemistry In silico science Inorganic chemistry Pharmacognosy Health statistics Forensic science Biochemistry Pharmacology Pharmaceutical care and science Medicinal chemistry Analytical chemistry Physical pharmacy Natural product chemistry Toxicology Environmental science Molecular and cellular biology Biopharmacy and pharmacokinetics Pharmaceutical education Chemical biology Physical chemistry Pharmaceutical engineering Epidemiology Hygiene Regulatory science Immunology and microbiology Clinical pharmacy Miscellaneous.