■ Structure elucidation by LC-MS. Foreword

Analusis Pub Date : 2000-12-01 DOI:10.1051/ANALUSIS:2000280885

W. Niessen

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引用次数: 15

Abstract

Major steps in the history of LC-MS were made using interfaces that only allow soft ionisation techniques, resulting in (de)protonated molecules with little or no fragmentation. Thermospray interfacing from the mid 1980 onwards for the first time gave a glimpse on what LC-MS could really do. With the broad implementation of the atmospheric-pressure ionization and interfacing, viz. (pneumatically-assisted) electrospray ionisation and interfacing (ESI) and the heated nebuliser in combination with atmosphericpressure chemical ionisation (APCI), LC-MS became a powerful technique which could even be used by less experienced people. However, in addition, the most frequent use of LC-MS today is quite different from the initial objective indicated above. LC-MS has significantly changed the impact of MS in a laboratory, because with LC-MS the mass spectrometer has entered both laboratories and application areas in a way which was certainly not foreseen at the beginning of its history in the mid 1970’s [2]. Especially the large interest in routine quantitative analysis and peptide and protein analysis was not anticipated. With LC-MS being based on soft ionisation techniques, the development of LC-MS to some extent stimulated the developments in tandem mass spectrometry, especially in triple-quadrupole and ion-trap instruments. With the ability to fragment the even-electron protonated or deprotonated ions, generated in ESI and APCI, by means of collisioninduced dissociation (CID), the first steps in the direction to structure elucidation could be made. However, soon it was realised that in fact there is far less knowledge on the fragmentation of these even-electron ions compared to that of odd-electron ions [3], as generated in EI. Despite the fact that many authors tried and still try to cover this by incorrectly calling the (de)protonated molecule a ‘(de)protonated molecular ion’ [4], this difference is obvious and important when one starts to interpret the MS‐MS product-ion mass spectra. In addition, the interpretation of the product-ion mass spectra must actually be performed, because no spectral libraries were available which could be used to assist in the structure elucidation.

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■LC-MS结构解析。前言

LC-MS历史上的主要步骤是使用只允许软电离技术的界面，导致(去)质子化的分子很少或没有碎片。Thermospray接口从1980年代中期开始第一次让人窥见质真的可以做什么。随着大气压电离和界面的广泛实施，即(气动辅助)电喷雾电离和界面(ESI)和加热雾化器与大气压化学电离(APCI)相结合，LC-MS成为一种强大的技术，即使是经验较少的人也可以使用。然而，另外，目前LC-MS最常用的用法与上面提到的最初目标有很大的不同。LC-MS极大地改变了MS在实验室中的影响，因为LC-MS使质谱仪以一种在20世纪70年代中期其历史开始时肯定无法预见的方式进入了实验室和应用领域[2]。特别是对常规定量分析和肽和蛋白质分析的巨大兴趣是没有预料到的。由于LC-MS是以软电离技术为基础的，因此LC-MS的发展在一定程度上促进了串联质谱的发展，特别是在三重四极杆和离子阱仪器方面。通过碰撞诱导解离(CID)，可以将ESI和APCI中产生的质子化或去质子化的偶电子离子裂解，从而向结构解析方向迈出了第一步。然而，人们很快意识到，事实上，与EI中产生的奇电子离子[3]相比，对这些偶电子离子的碎片化的了解要少得多。尽管许多作者试图并且仍然试图通过错误地将(去)质子化分子称为“(去)质子化分子离子”来掩盖这一点[4]，但当人们开始解释MS - MS产物-离子质量谱时，这种差异是明显而重要的。此外，由于没有可用的光谱库来辅助结构解析，因此必须实际进行产物离子质量谱的解释。

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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Analusis

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