氨基糖苷类抗生素分析方法的研究进展

对近20年来氨基糖苷类抗生素分析方法的进展进行了评述,其中包括微生物法、分光光度法、发光分析法、免疫分析法、色谱分析法、电化学分析法、共振瑞利散射法以及其他一些分析方法。引用文献79篇。     

氨基酸的分析方法及其应用进展

从衍生试剂角度,介绍了不同衍生化氨基酸的分析方法,包括离子交换色谱法、高效液相色谱法、气相谱法和毛细管电泳法,以及无需衍生化的直接分析法高效阴离子交换色谱-积分脉冲安培法,并总结了蛋白质、食品和生理体液样品中的氨基酸分析方法。     

仪器分析原理及其在农业中的应用

本书是严国光,严衍录编著,由科学出版社1982年12月出版的新书。全书分三编共16章,总计374,000字。讲述了光学分析法(紫外可见吸收光谱、红外光谱、原子吸收光谱、荧光法、发射光谱),色谱分析法(气相色谱、液相色谱、薄层色谱与纸色谱),电化学分析法(电位法、电导法、电解法、电化学容量分析)等方法的基本原理及这些方法在农业中的应用。着重阐述分析方法的原理、概念,帮助读者掌握分析方法的要领。     

土壤中砷形态分析研究进展

本文评述了近年来国内外土壤中砷形态分析的主要研究方法,包括联用分析法、分级提取法和同步辐射X-射线线吸收光谱法。联用分析法包括气相色谱联用法、毛细管电泳联用法和高效液相色谱联用法。重点介绍了目前应用范围较广的高效液相色谱-等离子体质谱(HPLC-ICP-MS)联用法和高效液相色谱-氢化物发生-原子荧光光谱(HPLC-HG-AFS)联用法。同步辐射X-射线线吸收光谱法近几年发展迅速,是最具发展潜力的形态分析方法。     

15％哒螨灵乳油的气相色谱测定分析

采用气相色谱分析法,以实验室较常用AgilentDB -1毛细管色谱柱为分离柱,选择氢火焰离子化检测器,建立一种适合实验室开展哒螨灵质量分数检测的分析方法,经保留时间定性确证,峰面积外标法进行定量分析.结果表明,哒螨灵的线性相关系数为0.99913;变异系数为0.21％;平均回收率为98.38％.     

在环境科学与生命科学研究中广泛应用的元素形态分析研究进展

按测试方法分类,包括电化学分析方法、毛细管电泳法,分子活化分析法,计算机模拟以及以气相色谱、高效液相色谱,流动注射等为基础的联用技术,对近lO年来广泛应用于环境与生命科学的国内外元素形态分析研究进展进行了综述。     

土壤中氨基酸分析方法的研究进展

本文对土壤中氨基酸的分析方法做了较详细的评述,并针对土壤氨基酸的特点,就土壤样品的前处理(主要包括水解和纯化)及目前常用的色谱分离分析方法进行了总结(主要包括柱后衍生阳离子交换色谱、气相色谱、柱前衍生反相高效液相色谱、阴离子交换色谱-积分脉冲安培检测等方法)。     

食品及食品包装材料中光引发剂分析方法的研究进展

综述了食品及食品包装材料中光引发剂分析方法的研究进展,包括样品的前处理方法(如固相萃取、固相微萃取、基质分散固相萃取、加速溶剂萃取、分散液液微萃取、凝胶渗透色谱)和分析方法(如气相色谱-质谱法、气相色谱-串联质谱法、液相色谱法、液相色谱-串联质谱法、超高效合相色谱法),并对其发展趋势作了展望。     

乳清酸/异乳清酸体系荧光法测定铕、铽、镝

对比研究了乳清酸和异乳清酸对某些稀土离子特征荧光的增敏情况，发现异乳清酸比乳清酸更有效地使Eu^3 、Tb^3 、Dy^3 的特征荧光增敏。建立了乳清酸，异乳清酸体系荧光法测定Eu^3 、Tb^3 、Dy^3 的新方法，在乳清酸体系中Eu^3 、Tb^3 、Dy^3 的检出限分别是0．73、0．065mg，L，在异乳清酸体系中Eu^3 、Tb^3 、Dy^3 的检出限分别是0．88、0．0023、0．59mg/L。该方法用于混合稀土氧化物中Eu^3 、Tb^3 、Dy^3 含量的测定，结果满意。     

后目标分析法用于盐益智仁挥发性成分的顶空-气相色谱-四级杆/飞行时间质谱分析

后目标分析法用于中药挥发性成分分析,可对复杂基体实行快速、准确、宽范围的分析,成功解决了化合物因共洗脱、柱流失等干扰无法定性的问题. 气相色谱-质谱检测的结果运用图谱检索结合保留指数和准确质量的后目标分析方法从盐益智仁挥发性成分中共鉴定出119个化合物. 通过保留指数推算保留时间,结合窄质量窗口提取离子色谱图的后目标分析方法降低了背景干扰,提高选择性,有利于复杂基体中痕量成分的分析,又鉴定出3个目标化合物. 此外,由串联质谱推测化合物裂解规律,辅以二级质谱中碎片离子准确质量,又鉴定出一个化合物.     

Quantitative screening and matrix effect studies of drug discovery compounds in monkey plasma using fast-gradient liquid chromatography/tandem mass spectrometry.

A higher-throughput bioanalytical method based on fast-gradient (1 min run time) high-performance liquid chromatography (HPLC) coupled with tandem mass spectrometry (MS/MS) was developed for screen-type analyses of plasma samples from early drug discovery studies in support of exploratory pharmacodynamic studies. The HPLC system equipped with minibore column was interfaced with either atmospheric pressure chemical ionization (APCI) or electrospray (ESI) ionization techniques. The matrix ion suppression effect of both quantitative HPLC/MS/MS analyses was compared using the post-column infusion system. The use of the described methods provided advantages such as a shorter chromatographic region of ion suppression, less solvent consumption and shorter run times in comparison with standard analytical column HPLC/MS/MS methods. The analytical results obtained by both HPLC/MS/MS methods were in good agreement (within 15% of error) and displayed a good correlation with the pharmacodynamic outcome.     

Fast LC/MS in the analysis of small molecules

Liquid chromatography-mass spectrometry (LC/MS) has become one of the most widely used analytical techniques in both qualitative and quantitative analysis of small molecules. Recently, with the increasing demand for ever-higher sample throughput, the use of faster chromatographic separations has become popular, along with other LC/MS methods that decrease analytical cycle-time. The burgeoning use of LC/MS has meant that the primary expertise of many practitioners today is not in the field of LC/MS, which has been facilitated by the ease-of-use of modern LC/MS systems. An examination of the current state of the literature, relating to "fast LC/MS", should serve well to those new to LC/MS, and should help them in the development of fast LC/MS methods that are effective in terms of both the chromatography and the utilization of the mass spectrometer. This review paper focuses on fast LC/MS analyses of small molecules that have been reported in peer-reviewed publications.     

Coupling techniques in LC/MS and SFC/MS

Summary Techniques and applications of analytical instruments combining a chromatographic technique, including liquid chromatography and supercritical fluid chromatography, with mass spectrometry (LC/MS and SFC/MS), that have appeared over the past five years, are reviewed and discussed. It is shown that still many different methods co-exist and have both specific advantages and limitations. SFC/MS appears easier to run for many compounds so far analysed by conventional LC/MS methods. On the other hand, new LC/MS methods that use fast atom bombardment or electrospray ionization have the greater potential for the investigation of polar biopolymers.     

Comparison of analytical approaches for liquid chromatography/mass spectrometry determination of the alcohol biomarker ethyl glucuronide in urine

Official guidelines originating from a European Union directive regulate requirements for analytical methods used to identify chemical compounds in biological matrices. This study compared different liquid chromatography/electropray ionization mass spectrometry (LC/ESI‐MS) and tandem mass spectrometry (LC/ESI‐MS/MS) procedures for accurate determination of the conjugated ethanol metabolite and alcohol biomarker ethyl glucuronide (EtG) in urine, and the value of combined EtG and ethyl sulfate (EtS) measurement. Analysis was carried out on 482 urines following solid‐phase extraction (SPE) sample cleanup or using direct injection of a diluted sample. SPE combined with LC/MS/MS was demonstrated to be the most selective and sensitive method and was chosen as reference method. The EtG results by different methods showed good correlation (r = 0.96–0.98). When comparing five reporting limits for EtG in the range 0.10–1.00 mg/L, the overall agreement with the reference method (frequency of true positives plus true negatives) was 82–97% for direct‐injection LC/MS/MS, 90–97% for SPE‐LC/MS, 86–98% for direct‐injection LC/MS, and 86–98% for direct‐injection LC/MS analysis of EtG and EtS. Most deviations were attributable to uncertainty in quantitation, when the value was close to a cutoff but the respective results were slightly above and below, or vice versa, the critical limit. However, for direct‐injection LC/MS/MS, despite earning 4 identification points, equally many negative results were due to a product ion ratio outside the ±20% deviation accepted by the guidelines. These results indicate that the likelihood of different analytical methods to provide reliable analytical results depends on the reporting limit applied. Copyright © 2010 John Wiley & Sons, Ltd.     

Protocols for optimizing MS/MS parameters with an ion-trap GC-MS instrument

The product ion spectrum allows us to achieve very selective detection of pesticides and to eliminate the ambiguities caused by more conventional analytical approaches. Owing to the enhanced capabilities of GC/MS/MS for multiresidue pesticides, the development of a GC/MS/MS pesticides library will be useful. The aim of this study was to develop a sensitive and specific analytical method for the identification and quantification of compounds without the need of a time-consuming procedure. Two methods were studied in order to optimize the nonresonant conditions of dissociation of five pesticides (deltamethrin, metalaxyl, myclobutanil, procymidone, pirimicarb). The first permits a systematic investigation of the influence of the qz trapping parameter on sensitivity in precursor ion detection and on the efficiency of collision-induced dissociation (CID). The second is more suited for analytical laboratories and less time-consuming and allows us to reach similar results: the experiments were conducted step by step at a constant stability parameter.     

Proteomic LC-MS systems using nanoscale liquid chromatography with tandem mass spectrometry

Current nano-scale liquid chromatography-tandem mass spectrometry (nanoLC-MS/MS) approaches in proteome research are reviewed from an analytical perspective. For comprehensive analysis of cellular proteins, analytical methods with higher resolution, sensitivity, and wider dynamic range are required. Miniaturized LC coupled with tandem mass spectrometry is currently one of the most versatile techniques. In this review, the current status of nanoLC-MS/MS systems as well as data management systems is addressed. In addition, the future prospects for complete proteomics are discussed.     

Capillary electrophoresis and ultra-high-performance liquid chromatography methods in clinical monitoring of creatinine in human urine: A comparative study

Creatinine is an important diagnostic marker and is also used as a standardization tool for the quantitative evaluation of exogenous/endogenous substances in urine. This study aimed at evaluating and comparing three analytical approaches, based on hyphenations of different separation [two-dimensional capillary isotachophoresis (CITP–CITP), capillary zone electrophoresis (CZE), ultra-high-performance liquid chromatography (UHPLC)] and detection [conductivity (CD), ultraviolet (UV), tandem mass spectrometry (MS/MS)] techniques, for their ability to provide reliable clinical data along with their suitability for the routine clinical use (cost, simplicity, sample throughput). The developed UHPLC–MS/MS, CITP–CITP–CD, and CZE–UV methods were characterized by favorable performance parameters, such as linearity (r ˃ 0.99), precision (relative standard deviation, 0.22–2.97% for the creatinine position in analytical profiles), and recovery (87.1–115.1%). Clinical data, obtained from the analysis of 24 human urine samples by a reference enzymatic method, were comparable with those obtained by the tested methods (Passing–Bablok regression and Bland–Altman analysis), approving their usefulness for the routine clinical use. In this context, the UHPLC–MS/MS method provides benefits of enhanced orthogonality/accuracy and high sample throughput (threefold shorter total analysis times than the CE methods), whereas advantages of the CE methods for routine labs are simplicity and low cost of both the instrumentation and measurements.     

One-minute full-gradient HPLC/UV/ELSD/MS analysis to support high-throughput parallel synthesis

High-throughput parallel synthesis of library compounds for early drug discovery requires high-throughput analytical methods to confirm synthesis, identify reaction products, and determine purity. An ultrafast 1.0-min HPLC/UV/ELSD/MS method was developed and compared to our standard 2.5- and 5.0-min methods in order to determine if the faster method was appropriate to evaluate compound synthesis and determine purity. In addition to using standard test mixtures, a 400-member library produced by high-throughput parallel synthesis was used for comparing the various methods. Mass spectrometric detection was used for compound identification, while UV and ELSD data offered purity assessment. Compared to our longer separations, chromatographic separation achieved using the 1.0-min method was sufficient for compound evaluation and purity assessment. This ultrafast 1.0-min HPLC/UV/ELSD/MS method is expected to increase analytical throughput tremendously, provide important information faster, and reduce the overall cycle time from synthesis to screening.     

Use of an integrated MS--multiplexed MS/MS data acquisition strategy for high-coverage peptide mapping studies

Liquid chromatography/mass spectrometry (LC/MS) peptide maps have become a basic tool for characterizing proteins of biological and pharmaceutical interest. The ability to generate reproducible maps with high protein sequence coverage is a central goal of methods development. We have applied a recently developed analytical approach (termed LC/MS(E)) to LC/MS peptide mapping. Using the LC/MS(E) approach, the mass detector alternates between a low-energy scanning mode (MS) for accurate mass peptide precursor identification, and an elevated-energy mode (MS(E)) for generation of accurate mass multiplex peptide fragmentation data. In this paper, we evaluate this analytical approach against a tryptic digest of yeast enolase. From the low-energy data, high peptide map coverage (98% of sequence from peptides >3 amino acids) was reproducibly obtained. The MS signal for essentially equimolar peptides varied over 2 orders of magnitude in intensity, and peptide intensities could be precisely and reproducibly measured. Using the temporal constraint that MS(E) peptide fragment ions exhibit chromatographic profiles that parallel the precursor ions that generated them, we were able to produce accurate mass time-resolved MS/MS information for all enolase peptides with sufficient abundance to produce a detectable fragment ion.     

Development of tandem mass spectrometry: one perspective

The historical roots of tandem mass spectrometry or MS/MS (an invaluable tool for determining molecular structure and mixture analysis) are reviewed from the perspective of an active participant. The driving force for creating the first (and only) five-sector tandem mass spectrometer in the period 1962–1965 was to establish mechanisms of low energy ion–molecule reactions unequivocally and to evaluate the dependence of these reactions on ion kinetic energy. The invention and deployment of several other specialized instruments in the 1970s (drift cell and tandem ion cyclotron resonance spectrometers, hybrid tandems, and triple quadrupole instruments) also had fundamental studies of ion reactions as the research objective. The focus on low energy ion chemistry has evolved into collisional activation, the basis of analytical applications of MS/MS, as a natural evolution of scientific interest. The first such studies utilizing a crossed-beam hybrid MS/MS addressed single collision gas phase activation and has recently been extended to surface collision activation. The important parallel development of these methods and the metamorphosis of MS/MS from a suite of research tools into analytical practice using commercial instrumentation are discussed briefly.