Studies on the content variation of chemical constituents during the combination of ginseng with veratrum nigrum by ESI-MS and HPLC-ESI-MS

To study the content variation of ginsenosides and alkaloids during combination of ginseng with veratrum nigrum, the ginsenosides and alkaloids in the decoction of ginseng with veratrum nigrum were analyzed and compared by high performance liquid chromatography-electrospray ionization-mass spectrometry (HPLC-ESI-MS) and electrospray ionization-mass spectrometry (ESI-MS). In the compatible decoction, eight ginsenosides and eight alkaloids. were detected, and the contents of six ginsenosides were found to be reduced, on the contrary, the contents of six alkaloids were increased. During combination of ginseng with veratrum nigrum, the contents of ginsenosides were reduced and those of the toxic alkaloids were increased. From the chemical point of view, the traditional theory is right that ginseng and veratrum nigrum are incompatible with each other.

HPLC-ESI-MS method development for the elucidation of nicardipine degradation products

Purpose: Nicardipine is a member of a family of calcium channel blockers named dihydropiridines that are known to be photolabile and may cause phototoxicity. It is therefore vital to develop analytical method which can study the photodegradation of nicardipine. Method: Forced acid degradation of nicardipine was conducted by heating 12 ml of 1 mg/ml nicardipine with 3 ml of 2.5 M HCl for two hours. A gradient HPLC medthod was developed using Agilent Technologies 1200 series quaternary system. Separation was achieved with a Hichrome (250 x 4.6 mm) 5 μm C18 reversed phase column and mobile phase composition of 70% A(100%v/v water) and 30% B(99%v/v acetonitrile + 1%v/v formic acid) at time zero, composition of A and B was then charged to 60%v/v A;40%v/v B at 10minutes, 50%v/v A; 50%v/v B at 30minutes and 70%v/v A; 30%v/v B at 35minutes. 20μl of 0.8mg/ml of nicardipine degradation was injected at room temperature (25oC). The gradient method was transferred onto a HPLC-ESI-MS system (HP 1050 series - AQUAMAX mass detector) and analysis conducted with an acid degradation concentration of 0.25mg/ml and 20μl injection volume. ESI spectra were acquired in positive ionisation mode with MRM 0-600 m/z. Results: Eleven nicardipine degradation products were detected in the HPLC analysis and the resolution (RS) between the respective degradants where 1.0, 1.2, 6.0, 0.4, 1.7, 3.7, 1.8, 1.0, and 1.7 respectively. Nine degradation products were identified in the ESI spectra with the respective m/z ratio; 171.0, 166.1, 441.2, 423.2, 455.2, 455.2, 331.1, 273.1, and 290.1. The possible molecular formulae for each degradants were ambiguously determined. Conclusion: A sensitive and specific method was developed for the analysis of nicardipine degradants. Method enables detection and quantification of nicardipine degradation products that can be used for the study of the kinetics of nicardipine degradation processes.

Development of Nanoinjector Devices for Electrospray Ionization - Tandem Mass Spectrometry (ESI-MSn)

In mass spectrometric (MS) systems with electrospray ionization (ESI), the sample can be analyzed coupled to separation systems (such as liquid chromatography or capillary electrophoresis) or simply by direct infusion. The greatest benefit of the type of injection is the possibility of continuous use of small amounts of samples over a long period of time. This extended analysis time allows a complete study of fragmentation by mass spectrometry, which is critical for structure elucidation of new compounds, or when using an ion trap mass analyzer. The injector filled with the sample is placed at the ESI source inlet creating an electric field suitable for the continuous formation of a spray (solvent and sample) and consequently, the gradual and even release of the sample. For the formation of the spray, is necessary that the injector end is metalized. The formation of a bilayer of titanium and gold provided an excellent attachment of the film, resulting in a nanoinjector for ionization/spray formation in the system for MS. The nanoinjectors showed high repeatability and stability over 100 min by continuous sampling with 10 mu L of sample.

Development of nanoinjector devices for electrospray ionization - tandem mass spectrometry (ESI-MSn)

In mass spectrometric (MS) systems with electrospray ionization (ESI), the sample can be analyzed coupled to separation systems (such as liquid chromatography or capillary electrophoresis) or simply by direct infusion. The greatest benefit of the type of injection is the possibility of continuous use of small amounts of samples over a long period of time. This extended analysis time allows a complete study of fragmentation by mass spectrometry, which is critical for structure elucidation of new compounds, or when using an ion trap mass analyzer. The injector filled with the sample is placed at the ESI source inlet creating an electric field suitable for the continuous formation of a spray (solvent and sample) and consequently, the gradual and even release of the sample. For the formation of the spray, is necessary that the injector end is metalized. The formation of a bilayer of titanium and gold provided an excellent attachment of the film, resulting in a nanoinjector for ionization/spray formation in the system for MS. The nanoinjectors showed high repeatability and stability over 100 min by continuous sampling with 10 µL of sample.

A new sensitive method for the quantification of glyoxal and methylglyoxal in snow and ice by stir bar sorptive extraction and liquid desorption-HPLC-ESI-MS

In this study, the development of a new sensitive method for the analysis of alpha-dicarbonyls glyoxal (G) and methylglyoxal (MG) in environmental ice and snow is presented. Stir bar sorptive extraction with in situ derivatization and liquid desorption (SBSE-LD) was used for sample extraction, enrichment, and derivatization. Measurements were carried out using high-performance liquid chromatography coupled to electrospray ionization tandem mass spectrometry (HPLC-ESI-MS/MS). As part of the method development, SBSE-LD parameters such as extraction time, derivatization reagent, desorption time and solvent, and the effect of NaCl addition on the SBSE efficiency as well as measurement parameters of HPLC-ESI-MS/MS were evaluated. Calibration was performed in the range of 1–60 ng/mL using spiked ultrapure water samples, thus incorporating the complete SBSE and derivatization process. 4-Fluorobenzaldehyde was applied as internal standard. Inter-batch precision was <12 % RSD. Recoveries were determined by means of spiked snow samples and were 78.9 ± 5.6 % for G and 82.7 ± 7.5 % for MG, respectively. Instrumental detection limits of 0.242 and 0.213 ng/mL for G and MG were achieved using the multiple reaction monitoring mode. Relative detection limits referred to a sample volume of 15 mL were 0.016 ng/mL for G and 0.014 ng/mL for MG. The optimized method was applied for the analysis of snow samples from Mount Hohenpeissenberg (close to the Meteorological Observatory Hohenpeissenberg, Germany) and samples from an ice core from Upper Grenzgletscher (Monte Rosa massif, Switzerland). Resulting concentrations were 0.085–16.3 ng/mL for G and 0.126–3.6 ng/mL for MG. Concentrations of G and MG in snow were 1–2 orders of magnitude higher than in ice core samples. The described method represents a simple, green, and sensitive analytical approach to measure G and MG in aqueous environmental samples.

Taxonomy of Australian Funnel-web spiders using rp-HPLC/ESI-MS profiling techniques

The complex nature of venom from spider species offers a unique natural source of potential pharmacological tools and therapeutic leads. The increased interest in spider venom molecules requires reproducible and precise identification methods. The current taxonomy of the Australian Funnel-web spiders is incomplete, and therefore, accurate identification of these spiders is difficult. Here, we present a study of venom from numerous morphologically similar specimens of the Hadronyche infensa species group collected from a variety of geographic locations in southeast Queensland. Analysis of the crude venoms using online reversed-phase high performance liquid chromatography/electrospray ionisation mass spectrometry (rp-HPLC/ESI-MS) revealed that the venom profiles provide a useful means of specimen identification, from the species level to species variants. Tables defining the descriptor molecules for each group of specimens were constructed and provided a quick reference of the relationship between one specimen and another. The study revealed that the morphologically similar specimens from the southeast Queensland region are a number of different species/species variants. Furthermore, the study supports aspects of the current taxonomy with respect to the H. infensa species group. Analysis of Australian Funnel-web spider venom by rp-HPLC/ESI-MS provides a rapid and accurate method of species/species variant identification. (c) 2006 Elsevier Ltd. All rights reserved.

Multiresidue determination of pesticides in surface water by SPE-HPLC-ESI and SPE-UPLC-ESI tandem mass spectrometry (MS/MS- triple quadrupole analyser).

2009

芍药花色形成的化学机制及其化学分类研究

本文以9 个芍药野生种（15 份种质）、104 个品种及2 个牡丹芍药组间杂种的花瓣为材料，利用液质联用技术鉴定了花瓣中的色素成分并探讨了芍药花色形成的化学机制和化学分类法。 结果表明，芍药花中主要含有5 种花青素，即芍药花素-3，5-二葡糖苷（ peonidin-3,5-di-O-glucoside ， Pn3G5G ）; 矢车菊素-3 ， 5- 二葡糖苷（ cyanidin-3,5-di-O-glucoside ， Cy3G5G ）; 天竺葵素-3 ， 5- 二葡糖苷（ pelargonidin-3,5-di-O-glucoside ， Pg3G5G ）; 芍药花素-3- 葡糖苷（peonidin-3-O-glucoside，Pn3G）和矢车菊素-3-葡糖苷（cyanidin-3-O-glucoside，Cy3G）。此外，3 种微量的花青素首次在芍药中发现：它们分别为芍药花素-3-葡萄糖-5-阿拉伯糖苷（peonidin-3-O-glucoside-5-O-arabinoside，Pn3G5Ara）、矢车菊素-3- 葡萄糖-5- 半乳糖苷（ cyanidin-3-O-glucoside-5-O-galactoside ，Cy3G5Gal）和天竺葵素-3-葡萄糖-5-半乳糖苷（pelargonidin-3-O-glucoside-5-Ogalactoside，Pg3G5Gal）。特征花青素Cy3G5Gal 和Pg3G5Gal 仅在新疆芍药（Paeonia anomala L.）及其亚种川赤芍（P. anomala subsp. veitchii(Lynch) D. Y.Hong & K. Y. Pan）中被检测出来，表明它们属于同一个种。Pn3G5Ara 仅存在于欧洲的野生芍药花瓣中，表明中国野生芍药和欧洲芍药的花青素代谢途径不同。 芍药花瓣中主要含有11 种花黄素，均为黄酮醇类物质。包括栎精-3，7 二葡糖苷（ quercetin-3,7-di-O-glucoside ）、山奈酚-3 ， 7 二葡糖苷（kaempferol-3,7-di-O-glucoside）、异鼠李素-3，7 二葡糖苷（isorhamnetin-3,7-di-Oglucoside）、栎精-3-O-(6”-没食子酰基)-葡糖苷 [quercetin-3-O-（6”-O-galloyl）-glucoside] 、栎精-3- 葡糖苷（ quercetin-3-O-glucoside ）、山奈酚-7- 葡糖苷（ kaempferol-7-O-glucoside ）、山奈酚-3-O- （ 6”- 没食子酰基） - 葡糖苷[kaempferol-3-O-（6”-O-galloyl)-glucoside]、异鼠李素-3-O-（6”-没食子酰基）-葡糖苷 [isorhamnetin-3-O- （ 6”-O-galloyl ） -glucoside] 、山奈酚-3- 葡糖苷（kaempferol-3-O-glucoside）、异鼠李素-3-葡糖苷（isorhamnetin-3-O-glucoside）和山奈酚-丙二酰葡糖苷（kaempferol-malonyl-glucoside）。此外，查耳酮在黄色的栽培品种‘黄金轮’和牡丹芍药组间杂交种‘伊藤杂种’中首次被检测到。其化学结构为查耳酮-2’-葡糖苷（chalcononaringenin 2’-O-glucoside），它是花瓣表现出黄色的主要色素，它与黄色牡丹野生种‘滇牡丹’（P. delavayi Franchet）花瓣中主要黄色色素成分一致。 通过对所有芍药野生种和栽培品种的色素分析，研究发现花青素是芍药花瓣中主要的色素，其中Pn3G5G 是花瓣中含量最高的花青素苷，其次为Cy3G5G。3G 型糖苷仅在少数品种中检测出来。此外，黄酮醇是芍药花瓣中重要的辅助色素。山奈酚苷是花瓣中含量最高的黄酮醇类，其次是栎精。 多元线性回归分析的结果表明，芍药花色的形成主要与花瓣中Pn3G5G、Cy3G5G 和Pg3G5G 的含量及总花青素量（TA）有关。根据8 种花青素结构与花色组成，将国内的野生种和大部分品种进行了化学分类：所有样本聚成3 大类，聚类后的树状图与其花色、花色素组成数据相一致，直观反映了野生种和栽培品种花色形成的化学背景和表型相似性程度。 芍药成色机理和化学分类的初步研究，对芍药新花色育种具有重要意义：芍药鲜红色花的育种中，育种亲本应具有高的Cy3G 含量、低的辅助色素效应指数。选育深紫色花或紫黑色花的品种，亲本应具有高的Pn3G5G 含量和低的Pg3G5G 含量。

天然产物及相关复方配伍的质谱及液相色谱研究

质谱技术以其灵敏度高、样品需求量少、快速准确的特点在生物大分子体系和天然产物的化学成分研究中起着极为重要的作用。特别是软电离质谱技术的发展，大大简化了化合物的测定过程，提高了分析研究速度，为分析植物及食物中的结构信息提供了快速便捷的方法。HPLC-ESI-MSn是90年代发展成熟的分析技术，它集液相色谱的高分离能力与质谱的高灵敏度和高专属性于一体，已成为包括药物微量杂质、药物降解产物、药代代谢动力学研究、组合化学合成产物高通量分析以及天然产物的化学筛选在内的现代药学研究领域最强有力的分析工具之一。本文首先采用电喷雾多级串联质谱技术，系统地研究了负离子条件下黄酮普元、黄酮醇普元以及二氢黄酮普元等化合物的特征质谱行为，并对中药黄芬中三种黄酮昔化合物进行了研究。利用这些特征碎片离子，可以简便快捷的区分结构类似的黄酮类化合物及其同分异构体。通过对黄酮C一昔类化合物的电喷雾串联质谱（ESI-MSn）研究，提出黄酮C-苷类化合物的特征碎裂规律，证明〔M-H-60］-，〔M-H-90］-，〔M-H-120〕-为黄酮C-苷类化合物的特征离子。为鉴定植物粗提物中黄酮类化合物奠定了基础。之后我们进一步采用高效液相色谱与电喷雾质谱联用技术，在线区分混合物中的黄酮类化合物的同分异构体。根据黄酮类化合物的电喷雾质谱规律以及化合物的色谱保留时间分析鉴定了黄答中的七种黄酮类化合物。建立了一种有效检测黄芩（Scutellariabaicalensis Georgi）中黄酮类化合物的快速灵敏的分析方法，为建立黄答药材的质量控制标准提供了借鉴。对于黄酮类化合物灵敏、快速和准确的分析方法的建立，不仅为黄酮类化合物的结构的快速鉴定提供了一定的依据，而且对生药的鉴别和制剂的质控起到重要的作用。利用电喷雾多级串联质谱技术，对化学结构相似的黄酮营、二氢黄酮营和黄酮醇昔类化合物进行了对比研究。并且首次利用高分辨质谱FTICR-MS及SORI-CID技术对naringin进行了质谱研究。利用其超高分辩率、准确质量确证了中性碎片丢失，进一步证明了我们对其碎裂机理的推断。之后，我们通过金属离子与黄酮昔溶液混合后，采用电喷雾串联质潜法进行测定。实验表明通过人为加入某些金属离子如Li+，Na+和K+，特别是Li＋可以提高黄酮昔类化合物分析灵敏度，从而提供较多结构信息。并且在串联质谱中表现不同的碎裂行为，为黄酮类化合物结构分析提供补充信息。研究表明结合〔M-H］-，〔M＋Na〕+，〔M＋Li〕+离子串联质潜提供的信息，能够有效的鉴定黄酮普的结构。本文通过电喷雾串联质谱（ESI-MSn）和液质联机技术（HPLC-ESI-MS／MS）研究了原小聚碱型生物碱。首次利用高分辨质谱FTICR-MS和SORI-CTD技术对原小桨碱型生物碱进行了高分辨质谱研究，提出了各种碎片离子的碎裂途径，并总结了原小聚碱型生物碱的质谱碎裂规律，为鉴定此类型的生物碱提供了依据。之后通过电喷雾串联质谱研究了四种生物碱化合物质谱行为。最后我们利用液质联机技术（HPLC-ESI-MSn），通过与标准品的液相保留时间对照及原小聚碱型生物碱的质谱碎裂规律，建立了分析鉴定常用中药中原小聚碱型生物碱的快捷方法。并通过选择离子监控技术（SIM）提高了对于同分异构体的分离鉴定。通过色谱UV吸收峰定量研究了这四种药用植物中小璧碱和巴马汀的含量，为临床应用提供一定的化学基础，为建立中药质量控制标准及植物分类学提供一定的依据。采用HPLC法考察了常见的黄连药对组合煎煮对黄连中小聚碱、巴马丁煎出量的影响。为制药工艺的优化奠定了基础。之后我们以中药理论为指导，按药物性味对改良半夏泻心汤中各药进行分组，利用高效液相色谱分析了不同配伍条件下小璧碱、巴马丁煎出量的变化。为组方的合理性和科学性提供了一定的化学物质基础依据。

几种中药材的化学成分及其定性定量检测方法研究

本论文由四部分组成。第一部分报道了佛手参提取物的化学成分研究，建立了活性成分含量测定的高效液相测定和指纹图谱研究，采用液质联用技术鉴定了主要色谱峰；第二部分报道了丹参及其复方制剂的特征图谱研究；第三部分探讨了两面针生物碱的电喷雾质谱裂解规律，并采用液质联用技术分离鉴定了提取物中的多种生物碱。第四部分概述了液质联用在药物代谢研究中的运用。 第一部分包括第一、第二和第三章。第一章针对佛手参（Gymnadeniaconopsea）块茎的甲醇提取物，采用大孔树脂和反相硅胶柱层析等各种分离方法，共分离鉴定出4 个化合物，通过波谱分析将它们的结构确定为dactylorhin B (1)、loroglossin (2)、dactylorhin A (3)和militarine (4)。这4 个化合物均是首次从佛手参中分离得到的琥珀酸葡萄糖苷类成分。第二章采用高效液相色谱法对西藏、四川、河北、青海和尼泊尔等不同地区产的十个佛手参样品进行腺嘌呤核苷和对羟基苯甲醇的定量分析，结果表明这2 个成份可视为佛手参的特征成分，但也注意到产地不同该2 个特征成分的含量也有所不同。第三章采用标准中药指纹图谱相似度计算软件，以10 个佛手参样品HPLC 图谱的平均值为相似性评价对照模板，对10 个样品进行了相似度评价，并经液质联用分析指认了7 个共有峰，分别为腺嘌呤核苷(1)、对羟基苯甲醇(2)、对羟基苯甲醛(3) 、dactylorhin B(4) 、loroglossin(5)、dactylorhin A(6)和militarine(7)。 第二部分包括第四、第五、第六和第七章。第四章运用电喷雾质谱检测了对照药材和五个不同产地的丹参药材中脂溶性和水溶性成分，系统地探讨了多种成分的电喷雾质谱规律，并以对照药材为标准建立了特征指纹图谱。五个产地的药II材通过与对照药材相对比，采用聚类分析的方法，得到了定性的鉴别与判断。并采用液质联用技术对丹参药材提取液中的化学成份进行分析，推测了九个特征峰，并对六样品的液相色谱图进行了聚类分析。第五章探讨了三七皂苷的电喷雾质谱电离和裂解规律，并采用电喷雾质谱法对三七标准药材，血通片中的皂苷成分进行了分析。第六章运用电喷雾质谱研究复方丹参片提取液的特征图谱，并和单味药材丹参和三七的特征图谱进行了对比研究。并运用HPLC-ESI MSn 分析鉴定了复方丹参片提取液中的化学成分，推测了12 个色谱峰。第七章总结了电喷雾质谱和液质联用技术在丹参药材，三七药材及复方丹参制剂中的运用的优势和局限性。 第三部分（第八章）研究了两面针生物碱中二氢白屈菜红碱(1)、二氢两面针碱(2)、8-酮基二氢白屈菜红碱(3)、8-丙酮基二氢两面针碱(4)、两面针碱(5)、和1,3-二(8-二氢两面针碱)丙酮(6)等六个苯并菲啶型生物碱的电喷雾质谱裂解规律，其中二氢两面针碱和二氢白屈菜红碱，8-丙酮基二氢两面针碱和8-酮基二氢白屈菜红碱是两对二个甲氧基分别在C-9 和C-10，C-10 和C-11 的同分异构体。实验结果表明，在相同的碰撞能下，这类位置异构体的ESI MS2 质谱二级碎片离子的相对峰度存在很大差异，这可以用于区分该类同分异构体，采用液-质联用可以对两面针的总生物碱提取物中的这些同分异构体加于区分。同时在本实验采用的液相色谱条件下，多种生物碱得到较好的分离，通过和对照品的保留时间，紫外吸收光谱及电喷雾质谱图对照，鉴定了11 个主要色谱峰。 第四部分（第九章）对液质联用技术在药物代谢中的运用进行了综述。 This dissertation consisted of four sections. The first two sections elaborated thephytochemical investigation of the rhizomes Gymnadenia conopsea R. Br., methoddevelopment for rapid identifying and qutifying the chemical condtituent of thistibetant medicine, and the chemical fingerprint analysis of rhizomes of G. conopsea,Salviae miltiorrhiza and P. notoginseng. The third section studied the fragmentationmechanism of six alkaloids from Zanthoxylum nitidium and method development forrapid identifying varieties of alkaloids from the extract of this herbal medicine. Thefourth section reviewed HPLC- MS method in drug metabolism studies. The first section consisted of chapters 1, 2, 3. Chapter 1 elaborated the phytochemicalinvestigation of Gymnadenia conopsea R. Br. Four succinate derivative esters wereisolated from the methanol extract of the rhizomes of G. conopsea through repeatedcolumn chromatography on normal and reversed phase silica gel, their structures weredetermined by ESI-MS, 1D and 2D NMR evidence. They were firstly discoveredfrom this species. In chapter 2, a high-performance liquid chromatography.diodearray detection (HPLC-DAD) method has been firstly developed for quantitation oftwo characteristic constituents, adenosine and 4-hydroxybenzyl alcohol, from theextract of rhizomes of G. conopsea. All 10 samples of G. conopsea contained differentamount of adenosine and 4-hydroxybenzyl alcohol. Adenosine and the4-hydroxybenzyl alcohol can be applied in identification and quality control for theroots of G. conopsea. In chapter 3, a high-performance liquid chromatography.diodearray detection.tandem mass spectrometry (HPLC-DAD-MSn) method has been firstly developed for chemical fingerprint analysis of rhizomes of G. conopsea andrapid identification of major compounds in the fingerprints. Comparing the UV andMS spectra with those of authentic compounds, seven main peaks in the fingerprintswere identified as adenosine, 4-hydroxybenzyl alcohol, 4-hydroxybenzyl aldehyde,dactylorhin B, loroglossin, dactylorhin A and militarine. The Computer AidedSimilarity Evaluation System for Chromatographic Fingerprint of TraditionalChinese Medicine (CASES) was employed to evaluate the similarities of 10 samplesof the rhizomes of G. conopsea collected from Sichuan, Qinghai and Hebei provincesand Tibet autonomous region of China, and Nepal. These samples from differentsources had similar chemical fingerprints to each other. The second section consisted of chapters 4, 5, 6 and 7. In chapter 4，both thecharacteristic spectra of liposoluble tanshinones and aqueous-soluble salvianolic acidswere established by the electrospray ionization mass spectrometry (ESI MS)technique and the differences between standard and crude rhizomes of Salviaemiltiorrhiza Bge. from 5 sources were analyzed. The law of electrospray ion trap mass(ESI ITMS) of typical tanshinones and salvianolic acids is studied.The analysis of the chemical constituent of rhizomes of Salviae miltiorrhiza Bge. byliquid chromatography coupled with mass spectrum (LC/MS) technique wasestablished，and the distances among standard herb and crude herb from 5 sourceswere calculated by clustering analysis. According the DAD spectra and MS2 data，9tanshinones could be speculated. In chapter 5, the character spectra of total saponinsin P. notoginseng extracts were established by ESI ITMS and selective ion monitoring(SIM) technology. The law of notoginsenosides by ESI MS2 was studied. In chapter 6,the characteristic spectra of Compound Danshen Tablet established and compared byESI-MS and HPLC/DAD/MS, 6 known tanshinones and 3 saponins were speculated.In chapter 7, the advantage and disadvantage of the strategy, using the ESI ITMS andLC/MS techniques for study of characteristic spetra of danshen and Compound Danshen Tablet, were summerized. The third section (chapter 8) studied the fragmentation mechanism of six alkaloids,dihydronitidine, dihydrochelerythrine, 8-acetonyl dihydronitidine,8-acetonyldrochelerythrine, nitidine and 1,3-bis (8-dihydronitidinyl)-acetone, by ESIMSn. Tandem mass spectrometry experiments indicated that different substitutionsites of the methoxyl groups at C-9 and C-10 or at C-10 and C-11 determined thedifferent abundances of the MS2 fragmentation ions using the same collision energy.According to the different abundances of MS2 product ions, positional isomericbenzo[c] phenanthridine alkaloids can be differentiated. Moreover, ten constituents inthe crude alkaloids extract from the roots of Zanthoxylum nitidium were rapidlyidentified by high-performance liquid chromatography coupled with tandem massspectrometry (HPLC-MSn), through comparing the retention times and ESI MSn spectra with the authentic standards. The fourth section (chapter 9) is a review on HPLC-MS method development in drug metabolism studies.

高效液相色谱-质谱联用法分析龙胆中的环稀醚萜类成分

A rapid method was developed to analyze the extract of the Gentiana scabra Bge. by using high performance liquid chromatograghy-electrospray ionization multi-stage tandem mass spectrometry (HPLC-ESI-MSn). 5 compounds in Gentiana scabra Bge. are identified in the positive and negative mode. The research results demonstrate that the HPLC-ESI-MSn can quickly identified the components in Gentiana scabra Bge. . It also can provide the information of the relative molecular mass and chemical structure of the compounds in the extract of the Gentiana scabra Bge. .

五味子中木脂素类成分的高效液相色谱-电喷雾质谱研究

采用液相色谱-电喷雾质谱联用(HPLC-ESI-MSn)技术,对北五味子与南五味子中木脂素类成分进行了系统研究.通过HPLC-ESI-MS技术,获得了相应化合物的保留时间、紫外光谱和分子量等信息,利用电喷雾多级串联质谱技术(ESI-MSn),获得了相应化合物的结构信息.研究结果表明,北五味子与南五味子的主要木脂素成分除5个共有成分外其它成分差异较大,并且其共有成分含量差别较大.在此基础上,建立了简便、快速的北五味子与南五味子药材分析鉴定的新方法.

Studies on the flavones using liquid chromatography-electrospray ionization tandem mass spectrometry

Fragmentation pathways of nine flavone compounds have been studied by using electrospray ionization multi-stage tandem mass spectrometry (ESI-MSn). Analyzing the product ion spectra of flavonoids and aglycones, we observed some diagnostic neutral losses, such as *CH3, H2O, residue of glucose and gluconic acid, which are very useful for the identification of the functional groups in the structures. Furthermore, specific retro Diels-Alder (RDA) fragments for flavones with different hydroxyl substitution have also been discussed. The information is helpful for the rapid identification of the location site of hydroxyl substitution on flavones. Fragmentation pathways of C-glycosidic flavonoid have also been discussed using ESI-MSn, demonstrating ions [M-H-60](-), [M-H-90](-), [M-H-120](-) are characteristic ions of C-glycosidic flavonoid. According to the fragmentation mechanism of mass spectrometry and HPLC-MS data, the structures of seven flavones in Scutellaria baicalensis Georgi have been identified on-line without time-consuming isolation. The HPLC-ESI-MSn method for analyzing constituents in the Scutellaria baicalensis Georgi has been established.

pH值对人参皂苷溶出影响规律的液质联用研究

采用液质联用(HPLC-ESI-MSn)技术,对不同pH值(2.4~11.2)条件下人参皂苷的溶出变化规律进行了系统研究,并提出了不同人参皂苷化合物的特征质谱裂解规律.实验结果表明,中性及碱性溶液对人参皂苷的溶出影响不大,仅仅在溶出总量上有所差别;而酸性是影响人参皂苷溶出的一个主要因素,随着水溶液酸性的增强(pH<4),人参皂苷溶出的种类明显减少,表明较强酸性条件下人参皂苷的溶出受到了抑制.