Department of Analytical chemistry, Faculty of Chemical Engineering, UCT Prague, Technická 5, Prague 6 166 28, Czech Republic; Zentiva, k.s. Praha, U Kabelovny 130, Prague 10 102 37, Czech Republic.
Zentiva, k.s. Praha, U Kabelovny 130, Prague 10 102 37, Czech Republic.
J Pharm Biomed Anal. 2024 Jan 20;238:115861. doi: 10.1016/j.jpba.2023.115861. Epub 2023 Nov 10.
A case study on Sitagliptin drug products and Sitagliptin/Metformin drug products concerning contamination with N-nitrosamines was performed using two newly developed analytical methods for determination of N-nitroso-triazolopyrazine (NTTP; 7-nitroso-3-(trifluoromethyl)-5,6,7,8-tetrahydro-[1,2,4]triazolo[4,3-a]pyrazine) and its precursor triazolopyrazine (3-(trifluoromethyl)-5,6,7,8-tetrahydro-[1,2,4]triazolo[4,3-a]pyrazine). The method for determination of triazolopyrazine was previously unpublished, the method for determination of NTTP was published only for analysis of active pharmaceutical ingredient Sitagliptin and not the drug forms. Solving the N-nitrosamine contamination is requested by regulatory authorities all over the world and thus is vital for all pharmaceutical companies. The solution always requires a sensitive analytical method. Both newly developed methods use liquid chromatography coupled with mass spectrometry (single quadrupole analyzer in case of triazolopyrazine and triple quadrupole analyzer in case of NTTP). Separation of triazolopyrazine was achieved on a column Acquity CSH C18 using a mobile phase consisting of aqueous ammonium formate buffered at pH 4.2 and acetonitrile. Detection was performed using positive electrospray and selected ion monitoring at m/z 193. Separation of NTTP was achieved on a column Acquity HSS T3 using a mobile phase consisting of 0.1 % formic acid in water and methanol. Detection was performed using positive electrospray and multiple reaction monitoring at transitions m/z 222.15→42.05 (collision energy 17 eV) and m/z 222.15→192.15 (collision energy 11 eV). Two issues specific to NTTP and triazolopyrazine previously not described in scientific literature were successfully troubleshooted. Spontaneous degradation of Sitagliptin to triazolopyrazine and methyl (R)-3-amino-4-(2,4,5-trifluorophenyl)butanoate was solved by using N,N-dimethylformamide as sample solvent during development of the method for quantitation of triazolopyrazine. A bad peak shape of NTTP due to the presence of rotamers of NTTP was successfully troubleshooted by increasing column temperature. Both methods were used during an optimization study of manufacturing of Sitagliptin and Sitagliptin/Metformin drug products. The goal of the study was to decrease NTTP content in the final drug product under the strict legislative limit set by Federal Drug Agency. The efficacy of several solutions was proven, but could not be fully disclosed due to Intellectual Property Protection policy of Zentiva. Instead, a brief review of recently published strategies to cope with N-nitrosamine contamination is presented.
对西他列汀原料药和西他列汀/二甲双胍复方制剂中与 N-亚硝胺污染有关的情况进行了研究,使用了两种新开发的分析方法来测定 N-亚硝基三唑并嘧啶(NTTP;7-亚硝基-3-(三氟甲基)-5,6,7,8-四氢-[1,2,4]三唑并[4,3-a]嘧啶)及其前体三唑并嘧啶(3-(三氟甲基)-5,6,7,8-四氢-[1,2,4]三唑并[4,3-a]嘧啶)。三唑并嘧啶的测定方法以前没有发表过,NTTP 的测定方法仅发表用于分析活性药物成分西他列汀,而不是药物形式。解决 N-亚硝胺污染是全球监管机构的要求,因此对所有制药公司都至关重要。解决方案始终需要一种灵敏的分析方法。这两种新开发的方法都使用液相色谱-质谱联用(三重四极杆分析仪用于三唑并嘧啶,单四极杆分析仪用于 NTTP)。三唑并嘧啶的分离是在 Acquity CSH C18 柱上实现的,使用由 pH 值为 4.2 的甲酸铵缓冲的水溶液和乙腈作为流动相。检测采用正电喷雾和 m/z 193 处的选择离子监测。NTTP 的分离是在 Acquity HSS T3 柱上实现的,使用由 0.1%甲酸在水中和甲醇中的溶液作为流动相。检测采用正电喷雾和多重反应监测,在 m/z 222.15→42.05(碰撞能 17 eV)和 m/z 222.15→192.15(碰撞能 11 eV)处进行。成功解决了之前在科学文献中未描述的 NTTP 和三唑并嘧啶的两个特定问题。通过在开发三唑并嘧啶定量方法时使用 N,N-二甲基甲酰胺作为样品溶剂,成功解决了西他列汀自发降解为三唑并嘧啶和甲基(R)-3-氨基-4-(2,4,5-三氟苯基)丁酸盐的问题。由于 NTTP 的旋转异构体的存在,NTTP 的峰形较差,通过增加柱温成功解决了这个问题。这两种方法都用于西他列汀和西他列汀/二甲双胍药物制剂制造的优化研究中。研究的目的是在联邦药物管理局设定的严格立法限制下降低最终药物产品中的 NTTP 含量。已经证明了几种解决方案的有效性,但由于 Zentiva 的知识产权保护政策,无法完全披露。相反,本文简要回顾了最近公布的应对 N-亚硝胺污染的策略。
