同位素质谱和无机质谱分析

本文与本刊1991年专栏评述衔接,评述了1991～1992年10月间我国同位素质谱和无机质谱分析的情况。包括同位素分析、同位素示踪、同位位素稀释、同位素质谱计研制、火花质谱、二次离子质谱、离子探针、等离子体质谱等。资料来源以国内为主,也收集了少量代表学科先进水平的外国文献。参考文献252篇。     

同位素质谱与无机质谱分析

本文是《分析试验室》定期评述中“无机质谱分析”课题的第二篇评述文章,它增加了同位素质谱分析的内容,故将题目改为现今题目,它综述了1985年～1990年间同位素质谱和无机质谱的发展概况。其中包括同位素示踪、同位素稀释、火花源质谱、二次离子质谱、等离子体质谱等。内容以国内为主,也收集了少量代表学科先进水平的外国文献。     

同位素质谱和无机质谱

本文是《分析试验室》定期评述中“同位素质谱和无机质谱”的第三次评述，评述的范围是１９９２年１１月至１９９４年１０月我国同位素质谱和无机质谱的进展。内容包括同位素质谱，同位素稀释质谱，二次离子质谱，离子探针，电感耦合等离子体质谱，激光电离质谱，加速器质谱、火花源质谱和它们在同位素地质年代学、同位素地球化学、核科学、农业、医学、环境学、计量学等学科中的应用。引用文献２５９篇．     

同位素质谱和无机质谱

本文是《分析试验室》定期评述中“同位素质谱和无机质谱”的第四篇评述，评述的范围是１９９４年１１月至１９９６年１０月我国气体同位素质谱，热电离同位素质谱，加速器质谱，火花源质谱，电感耦合等离子体质谱，辉光放电质谱，同位素稀释质谱，二次离子质谱，激光共振电离子飞行时间质谱，电子探针，质子探针，激光探针和它们在地学，核科学，环境科学，材料学，计理学，医学和生命科学中的应用，引用文献１４９篇。     

生物质谱

质谱已成为生物和生物化学研究的一个重要的分析工具，特别是在蛋白质组学研究的作用更显突出，它的分析速度、准确性和灵敏度都是传统分析技术所不可比拟的。主要介绍了两种近年来发展最为迅速、应用最为广泛的软离子化质谱技术：即基体辅助激光解吸离子化质谱（MALDI－MS）和电喷了子化质谱（ESI－MS）的原理、技术的最新进展，并简单介绍了它们在蛋白质和多肽分析中的应用。     

离子阱颗粒质谱研究进展

随着质谱技术的不断发展,对超高质量颗粒物质的分析已经成为质谱领域研究的一个重要方向.离子阱颗粒质谱(particle ion trap mass spectrometry)作为用于完整颗粒质量分析的有利工具,拓展了质谱技术在巨大颗粒物质量分析中的应用范围.本文对离子阱颗粒质谱仪器的研究进展及其在各个领域的应用进行了综述,并展望了离子阱颗粒质谱未来的发展趋势.     

质谱及色谱-质谱联用技术在多糖结构分析中的应用

综述了从1968-2010年间质谱及色谱-质谱联用分析法在多糖结构分析中的应用,包括电子轰击质谱、化学电离质谱、快原子轰击质谱、电喷雾质谱、基质辅助激光解吸离子化质谱、气相色谱-质谱、液相色谱-质谱和毛细管电泳-质谱法(引用文献42篇)。     

中药质谱分析方法及应用研究

分别从中药成分分析、活性筛选和代谢组学三方面对质谱技术在中药研究中的应用进展进行了全面综述.在中药成分分析方面,重点介绍了寡糖异构体的分析方法,以及质谱指纹图谱技术在中药成分分析及质量控制中的应用;在活性筛选方面,分别介绍了超滤-质谱、细胞膜色谱-质谱、微透析-质谱、亲和色谱-质谱、强度衰减质谱、修饰琼脂糖珠-质谱和直接分析质谱等技术及其应用;在代谢组学研究方面,对中药治疗肝损伤、肾虚、心肌梗死和糖尿病等疾病方面的研究进展进行了阐述.上述内容充分反映了质谱技术在中药创新性研究中的重要性.     

食用油甘油三酯质谱分析方法的研究进展

该文对质谱鉴定技术及其与色谱联用的分析方法(包括直接进样质谱分析、气相色谱质谱联用技术、超临界流体与质谱联用技术和液相色谱质谱联用技术)在甘油三酯分析方面的应用进行了综述,评述了各类分析方法的优缺点,对常用的脂质分析数据库进行了介绍,并对甘油三酯分析方法的发展及应用作了展望。     

质谱应用心得

有机化合物四大谱(质谱、核磁、红外、紫外)已成为有机化学学科中很重要的分析鉴定手段。从大学二年级起,我们学习了《仪器分析》、《仪器分析实验》、《有机化合物的光谱鉴定》等课程,但这些理论上的学习只在我们脑海中留下不明的,笼统的概念。直至做毕业论文时,我们将自己亲手合成的化合物进行质谱分析来鉴定证实,才对质谱有了进一步的较清晰的了解,巩固     

Comparison of mass resolution criteria in mass spectrometry

For a single peak, mass spectral resolution can be expressed in terms of peak width or ratio of peak position to peak width. Alternatively, for two equally intense peaks of equal width, resolution can be defined as the minimum peak separation such that the height of the valley between the combined peaks is less than a specified ratio (1%, 10%, 50%, 100%) of the individual (or combined) peak maximum. All these definitions depend on peak shape. Conversion formulae between various mass resolution criteria are presented for each of eight spectral peak shapes: Gaussian, triangular, trapezoidal, Lorentzian (absorption-mode, magnitude-mode, and sine-apodized magnitude-mode), and sinc (absorption-mode and magnitude-mode). From these formulae, mass resolutions based upon different criteria are readily compared for the same or different line shapes.     

Determination of micelle mass by electrospray ionization mass spectrometry

By electrospray ionization (ESI) mass spectrometry, micelle solutions of sodium cholate were investigated in detail in the presence and absence of ethanol. The average aggregation number could be evaluated from the spectra acquired under conditions where soft collisions adequate to measure the micelle solution were induced, and the value agreed well with that obtained previously by other methods. From the dependence on ethanol content, it was also found that the average aggregation number in aqueous solution without organic solvent could be reliably estimated. The ESI method proved to be a useful tool for determining the micelle mass in the original aqueous phase.     

The use of mass defect in modern mass spectrometry

Mass defect is defined as the difference between a compound's exact mass and its nominal mass. This concept has been increasingly used in mass spectrometry over the years, mainly due to the growing use of high resolution mass spectrometers capable of exact mass measurements in many application areas in analytical and bioanalytical chemistry. This article is meant as an introduction to the different uses of mass defect in applications using modern MS instrumentation. Visualizing complex mass spectra may be simplified with the concept of Kendrick mass by plotting nominal mass as a function of Kendrick mass defect, based on hydrocarbons subunits, as well as slight variations on this theme. Mass defect filtering of complex MS data has been used for selectively detecting compounds of interest, including drugs and their metabolites or endogenous compounds such as peptides and small molecule metabolites. Several strategies have been applied for labeling analytes with reagents containing unique mass defect features, thus shifting molecules into a less noisy area in the mass spectrum, thus increasing their detectability, especially in the area of proteomics. All these concepts will be covered to introduce the interested reader to the plethora of possibilities of mass defect analysis of high resolution mass spectra. Copyright © 2012 John Wiley & Sons, Ltd.     

Hybrid mass spectrometers for tandem mass spectrometry

Mass spectrometers that use different types of analyzers for the first and second stages of mass analysis in tandem mass spectrometry (MS/MS) experiments are often referred to as "hybrid" mass spectrometers. The general goal in the design of a hybrid instrument is to combine different performance characteristics offered by various types of analyzers into one mass spectrometer. These performance characteristics may include mass resolving power, the ion kinetic energy for collision-induced dissociation, and speed of analysis. This paper provides a review of the development of hybrid instruments over the last 30 years for analytical applications.     

Improved mass accuracy for tandem mass spectrometry

With the emergence of top-down proteomics, the ability to achieve high mass measurement accuracy on tandem MS/MS data will be beneficial for protein identification and characterization. (FT-ICR) Fourier transform ion cyclotron resonance mass spectrometers are the ideal instruments to perform these experiments with their ability to provide high resolution and mass accuracy. A major limitation to mass measurement accuracy in FT-ICR instruments arises from the occurrence of space charge effects. These space charge effects shift the cyclotron frequency of the ions, which compromises the mass measurement accuracy. While several methods have been developed that correct these space charge effects, they have limitations when applied to MS/MS experiments. It has already been shown that additional information inherent in electrospray spectra can be used for improved mass measurement accuracy with the use of a computer algorithm called DeCAL (deconvolution of Coulombic affected linearity). This paper highlights a new application of the strategy for improved mass accuracy in tandem mass analysis. The results show a significant improvement in mass measurement accuracy on complex electron capture dissociation spectra of proteins. We also demonstrate how the improvement in mass accuracy can increase the confidence in protein identification from the fragment masses of proteins acquired in MS/MS experiments.     

A Quadrupole mass spectrometer for resolution of low mass isotopes

The qualitative and quantitative identification of low mass isotopes in the mass range 1–6 u poses certain difficulties when attempting to achieve the required resolution with an instrument suitable for deployment within a process environment. Certain adjacent species present in the process sample (HT and D₂) require a resolution greater than 930 to achieve an accurate measurement. We demonstrate here through simulation techniques that this level of performance required is unachievable using commercially available instruments. Using previously reported simulation techniques, this article demonstrates how the required performance for resolving the low mass isotopes can be achieved by a quadrupole mass spectrometer (QMS), which incorporates a quadrupole mass filter (QMF) constructed from hyperbolic electrodes and operated in zone 3 of the Mathieu stability diagram.