实时直接分析质谱的原理及应用

新型常温常压离子化技术是近几年质谱学领域的一个研究热点。实时直接分析(direct analysis in real time,DART)作为该技术的一种,自2005年首次报道以来,已被应用于不同样品的分析。本文介绍了DART技术的发展过程、离子化机理以及影响DART离子化效率的参数,综述了其在活体果蝇费洛蒙检测、假药识别、墨水成分分析等方面的应用,并在结论部分对其应用前景进行了展望。     

常压敞开式离子化质谱技术研究进展

近年来,无需复杂样品前处理、且在开放环境下实现离子化的常压敞开式离子化质谱技术( Ambientionization mass spectrometry,AI - MS)的研制与应用成为质谱学领域的前沿及备受关注的研究方向.该文综述了AI离子源的基本原理、特征与应用进展,并结合笔者研制的空气动力辅助离子化(Air flow assisted ionization,AFAI)技术,介绍了气流辅助常压敞开式离子化技术的基本特点及其应用.展望了常压敞开式离子化技术的发展趋势.     

常压敞开式质谱成像技术及其应用

质谱成像将质谱的离子扫描技术与成像处理软件相结合,能有效地对分子的空间分布信息进行检测和成像;常压敞开式离子化技术的出现,为质谱成像提供了新的发展方向。本文对常压敞开式质谱成像技术及其应用进行了综述。     

常压电喷雾离子化的机理及应用

作为最有前景的分析仪器之一,质谱技术已在药物、食品、环境、人类健康、国家安全及相关领域展现出广阔的应用前景。不同种类的分析物具有多种特征,这为直接离子化及质谱分析增加了难度。常压敞开式离子源是近年来新兴的一种离子源,这类离子源具有无需复杂的样品前处理、操作方便、快速、非破坏性、灵敏度及特异性好、能实现实时原位、高通量分析等特点。本文综述了基于电喷雾离子化(ESI)原理的各种离子源的电离机理、特征及应用,展望了常压敞开式离子源的发展趋势。     

质谱技术在反应监测中的发展和应用

质谱因具有分辨率高、 灵敏度好、 响应快速以及结构鉴定能力强等特点, 近年来在反应监测研究领域应用广泛. 本文介绍了基于质谱的经典在线直接采样实时监测方案; 综合评述了常压质谱离子化技术在反应监测领域的发展和应用, 主要包括基于常压质谱的快反应监测、 微滴加速在长时间反应研究中的应用, 以及其它常压质谱在反应监测中的应用; 并对质谱在反应监测研究领域面临的挑战和发展趋势进行了总结和展望.     

复杂样品质谱分析技术的原理与应用

原位、实时、在线、非破坏、高通量、低耗损的质谱学方法是质谱分析技术发展的重要趋势.在无需样品预处理的条件下对复杂基体样品中痕量待测物直接离子化技术的出现,极大地提高了质谱分析的效率,使实际样品的快速质谱分析成为可能.本文着重综述了能够在无需样品预处理情况下对复杂基体样品离子化的新兴质谱技术及其应用研究,系统阐述了直接离子化技术的基本原理和方法,介绍了几种典型的常压直接离子化技术和装置,对直接离子化质谱分析技术在食品、药品、环境、活体分析、代谢组学、蛋白质组学以及生物组织质谱成像等领域的典型应用进行了述评,讨论了提高复杂样品快速质谱分析选择性的可能方法,并展望了常压直接离子化技术未来发展的可能趋势.     

等离子体常压解吸离子源质谱

近年来,常压开源质谱解吸/离子化(ambient desorption/ionization mass spectrometry)技术的开发促进了质谱分析的蓬勃发展.作为常压开源质谱技术的一大重要分支,基于等离子体的常压质谱解吸/离子化技术因无需样品预处理、无溶剂化过程、高灵敏度、高通量、能实时在线检测样品等优点,受到了学术界及仪器制造、化学和生物分析等相关产业界的广泛关注.本文从离子源的种类、原理及应用等角度对目前我国在开源质谱领域中自主研发的基于等离子体的常压离子源的研究进展进行了总结,并对此类等离子体常压离子源的发展进行了展望,重点涉及微波等离子体源、常压微辉光放电等离子体源和解吸电晕束离子源.     

常压敞开式质谱离子源发展趋势

近年来常压敞开式离子源凭借快速、原位、实时离子化样品等优势,被广泛应用于样品快速筛查、真伪鉴定、质谱成像等领域,已成为当今离子源的研究热点,受到了学术界及仪器制造、化学和生物分析等相关产业界的广泛关注。目前,该类离子源朝着克服基体效应、提高样品表面定位能力及增加离子传输距离等方向发展。本文主要介绍了可以很好解决上述问题并具有代表性的三种常压敞开式离子源:电喷雾萃取离子源(EESI)、介质阻挡放电离子源(DBDI)及空气动力辅助离子源(AFAI),重点涉及原理以及在此基础上所做的设计改进和应用进展。     

碳纤维离子化质谱技术的研究与应用

碳纤维离子化技术是一种新型敞开式质谱技术,可在开放式大气压环境下对各种形态的样品或样品表面物质进行检测,其分析成本低、通量高、简便、实时、快速,简化了工作流程,降低了样品的基质效应。该文从碳纤维离子化质谱技术的原理出发,介绍了影响其电离效率的主要因素,如碳纤维形态、碳纤维温度、碳纤维上所加电压、碳纤维与离子进样口的距离以及样品添加的方式,并对该技术近几年的改进和发展,及其在食品药品、法医毒物及生物样品、品种鉴别和环境分析等领域的应用进行了综述,详细介绍了其特点和优势。最后讨论了碳纤维离子化质谱技术存在的不足,以及未来可能的研究方向。     

介质阻挡放电离子源质谱分析

敞开式离子化质谱可对表面样品进行直接快速分析而受到关注,成为质谱分析的热点研究方向.介质阻挡放电离子源是一种基于等离子体放电机理的敞开式离子源,近年来得到了较快的发展.本文着重介绍该离子源的基本原理、性能特征以及应用进展,并对其发展趋势进行了展望.     

实时直接分析质谱在农药检测中的应用

实时直接分析(Direct analysis in real time,DART)作为一种原位电离技术发展迅猛,其与质谱联用已成为热门的分析技术并广泛应用于法庭科学领域,如食品安全、爆炸物检测、毒物毒品分析和药物分析等方面。目前农药的常规检测方法已非常成熟,但引入原位电离-质谱联用技术可以拓宽检测范围,缩短检测时限。该文从实时直接分析质谱(DART-MS)技术的工作原理、检测条件优化及其在农药检测方面的应用进行综述,并对DART-MS的应用前景进行了展望。     

Ambient analysis by thermal desorption atmospheric pressure photoionization

Ambient mass spectrometry has attracted substantial attention in recent years. Among ambient ionization methods, thermal desorption ionization stands out because of two attributes: (1) simplicity, rendering the technique suitable for in-field applications, and (2) ability to couple with a variety of gas-phase ionization methods thereby broadening the range of molecules that can be analyzed with this method. Here, we report on improving the performance of a direct analysis in real time (DART) source by implementing atmospheric pressure photoionization (APPI) downstream of the desorption region. At identical desorption and ion sampling conditions, APPI leads to detection of radical molecular ions from non-polar compounds that are absent from the spectra generated by DART alone. Moreover, a factor of 3–5 improvement in sensitivity is observed using APPI for positive ions commonly detected by DART and DART-APPI. Using helium and nitrogen as desorption gases, APPI shows identical performance regardless of desorption gas type. In contrast, a dramatic decrease in sensitivity is observed for DART operated with nitrogen compared to DART with helium. Comparable performance for DART and DART-APPI are observed in negative ion mode, although both show a drastic improvement in the absence of the Vapur interface. This interface creates a differentially pumped chamber prior to inlet of the mass spectrometer and reduces the mass spectrometer gas load when helium is used as desorption gas.     

Coupling of planar chromatography with Direct Analysis in Real Time mass spectrometry

Direct Analysis in Real Time mass spectrometry (DART-MS) is an emerging and rapidly developing area of ambient desorption ionization mass spectrometric techniques. Its coupling with planar chromatography is especially promising, as compared to other ambient desorption ionization techniques, because it does not require the use of liquids that may distort the shape of a spot by diffusion effects. In the first publications on TLC/HPTLC-DART-MS, due to the fixed, horizontally aligned supply of the gas flow from the DART ionization source to the MS inlet, the introduction of HPTLC/TLC plates as cut strips was inconvenient for quantitation, and the repeatability was very low due to the manual positioning. Recently a new version of the DART ion source was suggested, which allows adjusting the angle of the DART gas stream and the use of a motorized rail, thereby, improving highly the capabilities of TLC/HPTLC-DART-MS. This comprehensive review describes the development and analytical capabilities of TLC/HPTLC-DART-MS, and the general DART-MS perspectives for surface analysis or imaging MS.      

原位电离与小型质谱在公共安全领域的应用

质谱作为一种具有高准确度、高灵敏度、高选择性的检测仪器,在公共安全领域有着重要的应用前景。公共安全领域的需求主要涉及毒品、毒物、爆炸物等化学物质的现场快速检测,因其影响广泛,检测结果需非常准确。作为实验室分析仪器,质谱的准确性和速度能满足公共安全的应用需求,但作为现场快速检测的仪器仍需要一定改进。现场快速检测一方面要求检测仪器的小型化,另一方面要求样品前处理的简单化,以使整个检测流程可以无需专业人员来完成。对于检测仪器的小型化,小型质谱的开发在近20年得到了充分发展;对于样品前处理的简单化,研究者发明了原位电离技术,使得基质复杂的被分析物无需前处理即可进行质谱检测。该文首先介绍了原位电离技术的发展及其在公共安全领域的应用,特别是对解吸附电喷雾电离、实时直接分析电离、激光烧蚀电喷雾电离、纸喷雾电离与纸毛细管喷雾电离等典型原位电离技术的原理、性能及在公共安全领域的应用进行了详细介绍,并讨论了几种原位电离现场定量方法。然后,对原位电离小型质谱的发展进行了综述,从最初的小型化离子阱,到仅能检测可挥发有机物的小型质谱,再到可检测非挥发性物质的常规大气压电离源小型质谱,最后发展成为有原位电离源的小型质谱,历经20年的发展使得原位电离小型质谱得以出现和提升。并列举了原位电离小型质谱在毒品现场检测与吸毒人员排查、爆炸物现场侦察、食品安全之农用化学品检测、药物质量检查等公共安全领域的应用。最后,对原位电离小型质谱的发展进行了展望,指出原位电离与小型质谱相结合是小型质谱发展的必然趋势,未来需使用更加智能化的原位电离小型质谱,结合云数据平台,实现更方便广泛的应用。     

常压电离质谱在公共安全化学毒物检测的应用

常压电离质谱技术(Ambient ionization mass spectrometry,AIMS)以其敞开式环境、简便操作、原位、实时、高通量等优势,成为公共安全化学毒物检测领域的研究热点。该文基于文献计量分析,简要概述了AIMS的分类、发展趋势及其在公共安全化学毒物检测领域的发展现状,重点从检测灵敏度、样品前处理兼容性以及现场检测的小型化质谱适配性等方面,归类总结了AIMS在毒品、爆炸物、化学战剂和生物毒素等分析检测方面的应用特点,最后对其技术特点及未来发展待解决问题等进行了评述,为相关领域研究人员提供有益参考。     

The coupling of direct analysis in real time ionization to Fourier transform ion cyclotron resonance mass spectrometry for ultrahigh‐resolution mass analysis

Direct Analysis in Real Time (DART) is an ambient ionization technique for mass spectrometry that provides rapid and sensitive analyses with little or no sample preparation. DART has been reported primarily for mass analyzers of low to moderate resolving power such as quadrupole ion traps and time‐of‐flight (TOF) mass spectrometers. In the current work, a custom‐built DART source has been successfully coupled to two different Fourier transform ion cyclotron resonance (FT‐ICR) mass spectrometers for the first time. Comparison of spectra of the isobaric compounds, diisopropyl methylphosphonate and theophylline, acquired by 4.7 T FT‐ICR MS and TOF MS, demonstrates that the TOF resolving power can be insufficient for compositionally complex samples. 9.4 T FT‐ICR MS yielded the highest mass resolving power yet reported with DART ionization for 1,2‐benzanthracene and 9,10‐diphenylanthracene. Polycyclic aromatic hydrocarbons exhibit a spatial dependence in ionization mechanisms between the DART source and the mass spectrometer. The feasibility of analyzing a variety of samples was established with the introduction and analysis of food products and crude oil samples. DART FT‐ICR MS provides complex sample analysis that is rapid, highly selective and information‐rich, but limited to relatively low‐mass analytes. Copyright © 2010 John Wiley & Sons, Ltd.     

Characterization of direct-current atmospheric-pressure discharges useful for ambient desorption/ionization mass spectrometry

Two relatively new ambient ionization sources, direct analysis in real time (DART) and the flowing atmospheric-pressure afterglow (FAPA), use direct current, atmospheric-pressure discharges to produce reagent ions for the direct ionization of a sample. Although at a first glance these two sources appear similar, a fundamental study reveals otherwise. Specifically, DART was found to operate with a corona-to-glow transition (C-G) discharge whereas the FAPA was found to operate with a glow-to-arc transition (G-A) discharge. The characteristics of both discharges were evaluated on the basis of four factors: reagent-ion production, response to a model analyte (ferrocene), infrared (IR) thermography of the gas used for desorption and ionization, and spatial emission characteristics. The G-A discharge produced a greater abundance and a wider variety of reagent ions than the C-G discharge. In addition, the discharges yielded different adducts and signal strengths for ferrocene. It was also found that the gas exiting the discharge chamber reached a maximum of 235 °C and 55 °C for the G-A and C-G discharges, respectively. Finally, spatially resolved emission maps of both discharges showed clear differences for N₂⁺ and O(I). These findings demonstrate that the discharges used by FAPA and DART are fundamentally different and should have different optimal applications for ambient desorption/ionization mass spectrometry (ADI-MS).     

Ambient mass spectrometry: bringing MS into the “real world”

Mass spectrometry has recently undergone a second contemporary revolution with the introduction of a new group of desorption/ionization (DI) techniques known collectively as ambient mass spectrometry. Performed in an open atmosphere directly on samples in their natural environments or matrices, or by using auxiliary surfaces, ambient mass spectrometry (MS) has greatly simplified and increased the speed of MS analysis. Since its debut in 2004 there has been explosive growth in the applications and variants of ambient MS, and a very comprehensive set of techniques based on different desorption and ionization mechanisms is now available. Most types of molecules with a large range of masses and polarities can be ionized with great ease and simplicity with the outstanding combination of the speed, selectivity, and sensitivity of MS detection. This review describes and compares the basis of ionization and the concepts of the most promising ambient MS techniques known to date and illustrates, via typical analytical and bioanalytical applications, how ambient MS is helping to bring MS analysis deeper than ever into the “real world” open atmosphere environment—to wherever MS is needed.