检测活性药物成分、药物产品和其他基质中 N-亚硝胺杂质的分析方法

IF 3.7 3区 医学 Q2 CHEMISTRY, MEDICINAL Chemical Research in Toxicology Pub Date : 2024-08-19 DOI:10.1021/acs.chemrestox.4c0023410.1021/acs.chemrestox.4c00234
Krishna Moorthy Manchuri*, Mahammad Ali Shaik, Venkata Subba Reddy Gopireddy, Naziya Sultana and Sreenivasarao Gogineni, 
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引用次数: 0

摘要

自 2018 年以来,N-亚硝胺杂质已成为全球药品监管领域广泛关注的问题。产生这种担忧的原因在于其潜在的污染性、毒性、致癌性和致突变性,以及在许多活性药物成分、药物产品和其他基质中的存在。人体中的 N-亚硝胺杂质可导致严重的化学毒性效应。这些影响包括致癌作用、新陈代谢紊乱、生殖危害、肝脏疾病、肥胖、DNA 损伤、细胞死亡、染色体改变、先天缺陷和妊娠失败。它们尤其会导致肝脏、肺、鼻腔、食道、胰腺、胃、膀胱、结肠、肾脏和中枢神经系统等器官和组织发生癌症(肿瘤)。此外,N-亚硝胺杂质还可能导致阿尔茨海默氏症、帕金森氏症和 2 型糖尿病。因此,利用 LC-MS、GC-MS、CE-MS、SFC 等前沿分析技术,加强有效的分析方法来控制或避免这些杂质是非常重要的。此外,这些分析方法还需要具有灵敏度和选择性,以及适当的精度和准确度,这样才能适当地检测和量化药物中 N-亚硝胺杂质的实际含量。美国 FDA、EMA、ICH、WHO 等监管机构需要更加关注 N-亚硝胺杂质的危害,为药品生产商和申请者提供指导并定期更新。同样,药品生产商也应提高警惕,避免在生产过程中使用亚硝酸胺和仲胺。最近,许多研究人员发表了大量综述文章,重点介绍了在以前通报的产品(包括沙坦类、二甲双胍和雷尼替丁)中发现的 N-亚硝胺杂质。在许多其他产品中也发现了这些杂质。因此,本次审查旨在集中关注最近报告含有 N-亚硝胺杂质的产品。这些产品包括利福平、香必可、法莫替丁、尼扎替丁、阿托伐他汀、布美他尼、伊曲康唑、迪凡、依那普利、普萘洛尔、利辛普利、度洛西汀、利伐沙班、吡格列酮、格列酮、西洛他唑和舒尼替尼。
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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Analytical Methodologies to Detect N-Nitrosamine Impurities in Active Pharmaceutical Ingredients, Drug Products and Other Matrices

Since 2018, N-nitrosamine impurities have become a widespread concern in the global regulatory landscape of pharmaceutical products. This concern arises due to their potential for contamination, toxicity, carcinogenicity, and mutagenicity and their presence in many active pharmaceutical ingredients, drug products, and other matrices. N-Nitrosamine impurities in humans can lead to severe chemical toxicity effects. These include carcinogenic effects, metabolic disruptions, reproductive harm, liver diseases, obesity, DNA damage, cell death, chromosomal alterations, birth defects, and pregnancy loss. They are particularly known to cause cancer (tumors) in various organs and tissues such as the liver, lungs, nasal cavity, esophagus, pancreas, stomach, urinary bladder, colon, kidneys, and central nervous system. Additionally, N-nitrosamine impurities may contribute to the development of Alzheimer’s and Parkinson’s diseases and type-2 diabetes. Therefore, it is very important to control or avoid them by enhancing effective analytical methodologies using cutting-edge analytical techniques such as LC-MS, GC-MS, CE-MS, SFC, etc. Moreover, these analytical methods need to be sensitive and selective with suitable precision and accuracy, so that the actual amounts of N-nitrosamine impurities can be detected and quantified appropriately in drugs. Regulatory agencies such as the US FDA, EMA, ICH, WHO, etc. need to focus more on the hazards of N-nitrosamine impurities by providing guidance and regular updates to drug manufacturers and applicants. Similarly, drug manufacturers should be more vigilant to avoid nitrosating agents and secondary amines during the manufacturing processes. Numerous review articles have been published recently by various researchers, focusing on N-nitrosamine impurities found in previously notified products, including sartans, metformin, and ranitidine. These impurities have also been detected in a wide range of other products. Consequently, this review aims to concentrate on products recently reported to contain N-nitrosamine impurities. These products include rifampicin, champix, famotidine, nizatidine, atorvastatin, bumetanide, itraconazole, diovan, enalapril, propranolol, lisinopril, duloxetine, rivaroxaban, pioglitazones, glifizones, cilostazol, and sunitinib.

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来源期刊
CiteScore
7.90
自引率
7.30%
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215
审稿时长
3.5 months
期刊介绍: Chemical Research in Toxicology publishes Articles, Rapid Reports, Chemical Profiles, Reviews, Perspectives, Letters to the Editor, and ToxWatch on a wide range of topics in Toxicology that inform a chemical and molecular understanding and capacity to predict biological outcomes on the basis of structures and processes. The overarching goal of activities reported in the Journal are to provide knowledge and innovative approaches needed to promote intelligent solutions for human safety and ecosystem preservation. The journal emphasizes insight concerning mechanisms of toxicity over phenomenological observations. It upholds rigorous chemical, physical and mathematical standards for characterization and application of modern techniques.
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