Zhai Rongrong, Gao Wen, Li Mengning, Yang Hua
School of Traditional Chinese Pharmacy, China Pharmaceutical University, Nanjing 210009, China.
Se Pu. 2022 Sep;40(9):782-787. doi: 10.3724/SP.J.1123.2022.01028.
Ion mobility-mass spectrometry (IM-MS) is a combination of ion mobility separation and mass spectrometry technologies. In IM-MS, analytes are ionized by the ion source to form gas-phase ions, which are then rapidly separated using ion mobility based on their mobility difference, under the influence of both neutral buffer gas and an electric field, and then traversed and detected using mass spectrometry, which can separate ions based on mass-to-charge ratio. Furthermore, IM-MS could provide not only mass-to-charge ratio parameters like MS and MS spectra but also new structural information for component identification like collision cross-section values, drift time, arrival time, compensation voltage, and so on, which can be employed to resolve complex chemical components, especially indistinguishable isomers using mass spectrometry alone. In recent years, with the development of IM-MS technologies, IM-MS has become more widely employed in chemical analysis in traditional Chinese medicines (TCMs). Firstly, IM-MS was been successfully used in the separation of complex TCMs complex extract from interfering isobaric species. Secondly, IM-MS also offers new types of MS/MS fragmentation modes, and the combination of IM separation and fragmentation modes enables the acquisition of more specific and detailed fragment ion spectra. Thirdly, the collision cross-section is introduced by IM-MS, which is a unique physicochemical property of a component. Related data post-processing strategies based on experimentally derived collision cross-section values have been continuously developed in recent years to make full use of the collision cross-section values, these data post-processing strategies include collision cross-section database matching, theoretical collision cross-section values matching, machine-learning-based collision cross-section values prediction matching, mass-to-charge ratio versus collision cross-section correlation trend lines and so on. In doing so, these diverse strategies can greatly enhance the reliability and accuracy of the structural annotation of TCM compounds. This review primarily briefly introduces the major types and basic principles of IM-MS. The applications of IM-MS in TCM chemical analysis are highlighted in this study. The current applications of IM-MS in improving TCM chemical component separation are summarized, followed by a discussion of several strategies for enhancing separation selectivity. This review also offers some new fragmentation modes, novel data acquisition approaches, and collision cross-section data post-processing strategies applied in TCM qualitative analysis. Finally, the prospect of IM-MS applied in TCM chemical analysis is also discussed. This review provides approaches and ideas for future IM-MS research on TCM's chemical analysis.
离子淌度-质谱联用(IM-MS)是离子淌度分离技术与质谱技术的结合。在IM-MS中,分析物通过离子源电离形成气相离子,然后在中性缓冲气体和电场的共同作用下,基于它们的淌度差异利用离子淌度进行快速分离,接着通过质谱进行扫描和检测,质谱能够根据质荷比分离离子。此外,IM-MS不仅可以提供像质谱和质谱图那样的质荷比参数,还能提供用于成分鉴定的新结构信息,如碰撞截面值、漂移时间、到达时间、补偿电压等,这些信息可用于解析复杂化学成分,尤其是仅用质谱难以区分的异构体。近年来,随着IM-MS技术的发展,IM-MS在中药化学分析中的应用越来越广泛。首先,IM-MS已成功用于从干扰的等压物种中分离复杂中药提取物。其次,IM-MS还提供了新型的串联质谱碎裂模式,IM分离与碎裂模式的结合能够获取更特异、更详细的碎片离子谱。第三,IM-MS引入了碰撞截面,这是一种成分独特的物理化学性质。近年来,基于实验得出的碰撞截面值,不断开发相关的数据后处理策略以充分利用碰撞截面值,这些数据后处理策略包括碰撞截面数据库匹配、理论碰撞截面值匹配、基于机器学习的碰撞截面值预测匹配、质荷比与碰撞截面相关趋势线等。通过这些方法,这些多样的策略可以大大提高中药化合物结构注释的可靠性和准确性。本综述主要简要介绍了IM-MS的主要类型和基本原理。本研究重点介绍了IM-MS在中药化学分析中的应用。总结了IM-MS目前在改善中药化学成分分离方面的应用,随后讨论了几种提高分离选择性的策略。本综述还介绍了一些应用于中药定性分析的新碎裂模式、新型数据采集方法以及碰撞截面数据后处理策略。最后,还讨论了IM-MS应用于中药化学分析的前景。本综述为未来IM-MS在中药化学分析方面的研究提供了方法和思路。