绵参和地榆的化学成分研究

本论文由三章组成。第一章为综述，概述了植物中环烯醚萜类化合物的研究进展；第二和第三章为实验论文，分别报道了唇形科药用植物绵参和蔷薇科药用植物地榆的化学成分研究。 第一章概述了植物中环烯醚萜类化合物的研究成果，主要包括结构类型及药理活性等方面。 第二章包括两个部分。第一部分报道了藏药绵参（Eriophyton wallichii Benth）地上部分甲醇提取物的化学成分。采用正、反相硅胶柱层析等各种分离方法，从中共分离出7个化合物，有6个化合物为首次从该植物中分离得到，分别为β-谷甾醇（1），夏至草苦素（marrubiin，2），乌苏酸（3），cimigoside（4），5-deoxyantirrhinoside（5），8-表马钱子酸葡萄糖苷（8-epiloganic acid，6）和apigenin 7-(6''-p-coumaroyl)glucoside（7）。第二部分，采用高效液相色谱－质谱联用技术对绵参地上部分的甲醇提取物进行了分析，通过标准品对照紫、外光谱分析以及多级质谱分析与文献对照鉴定了8个成分，分别是：8-epiloganic acid（Ⅰ），quercitrin 3-glucoside-7-(6''-p-coumaroyl)glucoside（Ⅱ），ajugoside(I) （Ⅲ），chrysoeriol 7-O-E-p-coumaroyl-3-O-b-D-glucoside（Ⅳ），helichrysoside（Ⅴ），生物碱（Ⅵ），apigenin 2,3-dihydrogen-7-(6''-p-coumaroyl) glucoside（Ⅶ），apigenin 7-(6''-p-coumaroyl) glucoside（Ⅷ）。 第三章报道了中药地榆根部乙醇提取物正丁醇相的化学成分，通过正、反相硅胶柱层析等各种分离方法，从中分离得到8个化合物，分别为3,4¢- O-二甲基逆没食子酸（8），3,3¢,4¢-O-三甲基逆没食子酸（9）和3,4¢-O-二甲基逆没食子酸-4-O-b-D-木糖苷（10），19a-羟基-3-O-(a-L-阿拉伯糖)乌苏酸-28-O-b-D-葡萄糖苷（11）， 3b-[(a-L-arabinopyranosyl)oxy]-urs-11,13(18)-dien-28-oic acid b-D- glucopyranosyl ester（13），3-O-a-L-arabinopyranosyl-urs-12,18(19)-dien-28-oic acid b-D-glucopyranosyl ester（14），儿茶素（15），还有一种可能是皂苷11的工作产物（12）。 This dissertation consisted of three chapters. The first chapter elaborated the progress of iridoids occurring in plants. The later two chapters respectively elaborated the chemical constituents of Eriophyton wallichii Benth. and Sanguisorba officinalis L. The first chapter is a review of the research progress of iridoids occurring in plants, which includes their structure and pharmacology. The second chapter consisted of two parts. The first part is about the chemical constituents of methanol extraction from the aerial parts of Eriophyton wallichii Benth. Seven compounds were isolated and identified. Among them, the compounds of marrubiin, ursolic acid, cimigoside, 5-deoxyantirrhinoside, 8-epiloganic acid，apigenin 7-(6''-p-coumaroyl)glucoside were firstly reported in this plant. A HPLC-MSn method was developed for rapid identification of major compounds of Eriophyton wallichii. A total of 8 peaks in the chromatograms were unequivocally determined (peaks 1, 8) or tentatively identified (peaks 2-7) based on the detailed UV and tandem mass spectra analysis. Seven components were identified as 8-epiloganic acid（Ⅰ），Quercitrin 3-glucoside-7-(6''-p-coumaroyl)glucoside（Ⅱ），ajugoside(I)（Ⅲ），Chrysoeriol 7-O-E-p-coumaroyl-3-O-b-D-glucoside（Ⅳ），helichrysoside（Ⅴ），apigenin 2,3-dihydrogen-7-(6''-p-coumaroyl) glucoside（Ⅵ），apigenin 7-(6''-p-coumaroyl) glucoside（Ⅶ）。 The third chapter elaborated the chemical constituents of methanol extraction from Sanguisorba officinalis L, eight compounds were isolated from this plant by repeat column chromatography over silica gel. These compounds were identified as 3,4′-O-dimethylellagic acid, 3,3′,4′-O-trimethylellagic acid, 3,4′-O-dimethylellagic acid-4-O-b-D-xyloside, 3b-O-a-L-arabinopyranosyl-19a- hydroxyl-urs-12-en-28-oic acid 28-b-D-glucopyranoside, 3b-[(a-L-arabinopyranosyl)oxy]-urs-11,13(18)-dien- 28-oic acid b-D-glucopyranosyl ester，3-O-a-L–arabinopyranosyl-urs-12,18(19) -dien-28-oic acid b-D-glucopyranosyl ester, catechin.

几种植物药材的色谱－质谱联用分析

本论文由四章组成，第一、二、三章为实验论文，分别报道了中药羌活、菊花、全缘叶绿绒蒿的化学成分的高效液相色谱(HPLC)和液相色谱-质谱(LC-MS)联用分析以及挥发油的气相色谱-质谱(GC-MS)联用分析。第四章概述了重要藏药材化学成分的研究进展。 第一章首先对28批不同产地的羌活药材进行了HPLC分析，建立了羌活的指纹图谱。结果表明，不同产地羌活的化学成分基本相似，但是各组分在含量上存在较大差异。其次，对羌活的主要化学组分包括紫花前胡苷、紫花前胡素、6'-O-反式阿魏酸紫花前胡苷、茴香酸对羟基苯乙酯、羌活醇和异欧前胡素进行了定量分析。此外，针对同一产地不同采集时间的羌活挥发油进行系统分析，结果表明它们的化学成分基本相似，主要含有a－蒎烯、b－蒎烯、柠檬烯和龙脑乙酸酯等，只是各组分含量有所变化，这说明采集药材时要注意采集时间。 第二章分别报道了不同产地不同品种菊花非挥发性成分的液相色谱－二极管阵列检测－串联质谱(LC-PDA-MSn)分析和挥发性成分的气相色谱－质谱(GC-MS)联用分析比较。首先通过液相色谱－质谱－串联质谱对各色谱峰进行定性分析，通过与标准品对照，以及UV和MSn提供的结构信息，结合文献报道共鉴定了11个化学成分，包括绿原酸和10个黄酮化合物，并比较了不同品种菊花的化学成分相同之处和不同之处。另外，对七种不同品种不同产地的菊花挥发性成分通过GC-MS分析表明其主要挥发性成分为单萜类、倍半萜类化合物，共有成分樟脑、龙脑和龙脑乙酸酯等，各成分在不同挥发油中的含量变化明显。 第三章为藏药全缘叶绿绒蒿不同部位挥发油成分的气相色谱－质谱(GC-MS)联用分析，比较其挥发油化学成分及其含量变化的异同点。研究结果表明，全缘叶绿绒蒿花精油的化学成分明显多于全草部位，且两者主要成分有较大的差别。 第四章综述了青藏高原重要藏药材化学成分的研究进展。分别对藏药的资源特色和110多种常用重要藏药材的化学成分的研究情况以及藏药未来发展思路进行了阐述，以期对相关的研究提供一些信息。 This dissertation consists of four parts. The first part reports studies on the fingerprint of Notopterygium incisum and N. forbesii by HPLC-PDA-MSn, and on the constitutents of essential oil by GC-MS. The second part elaborates the chemical constitutents of Chrysanthemum L. by LC-MS and GC-MS analysis. The third part reports the chemical compositions of the essential oil from the different parts of Meconopsis integrifolia. The fourth part reviews on the progress of the studies on the chemical constitutents in Tibetan medicines. The first chapter is about HPLC analysis of a traditional Chinese herbal medicine Qiang-huo (Notopterygium incisum and N. forbesii ). Firstly, based on analyzing and contrasting the relative retention time and relative paek area in chromatographic fingerprint, the HPLC chromatographic fingerprint of Notopterygium incisum was established, which can used as a scientific basement for the quality evalution of this herb. Secondly, quantitative analysis were performed on the main chemical constitutents of Notopterygium incisum and N. forbesii including nodakenin, nodakenetin, 6’-O-trans-feruloylnodakenin, p-hydroxypenethylanisate, notopterol and isoimperatorin. The results indicated that the contents were variable related to different growth regions. Lastly, the essential oil of Notopterygium incisum collected in different harvest times is analyzed by GC-MS. The second chapter is about HPLC-MS and GC-MS analysis of several species of Chrysanthemum L. Firstly, eleven compounds including chlorogenic acid and ten flavone compounds were identified in the methanol extract of Chrysanthemum morifolium Ramat. from different regions by HPLC-MS analysis. Secondly, the essential oil of seven different species of Chrysanthemum L.were extracted by steam distillation, and its compositions were isolated and identified by GC-MS. The main active constitutents such as camphor, borneol and bornyl acetate were detected, but the relative content varied notably. The third chapter is about GC-MS analysis of the essential oil from different parts of Meconopsis integrifolia. It indicated great difference of the chemical compositions of their oil in the flowers and residual overground part. The last chapter is a review of the research progress of the Tibetan medicines, which includes their features and their main chemical constitutents.

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.

两种银莲花属植物的化学成分研究

本学位论文由5 章组成。第1 章报道了两头尖中三萜皂苷类化合物的全扫描电喷雾多级质谱分析及银莲花素A 的电喷雾质谱裂解规律；第2 和3 章报道了两种银莲花属药用植物化学成分的研究结果；第4 章报道了银莲花素A 的化学结构修饰及其对一种蛋白酪氨酸磷酸酯酶（PTP-1B）的抑制活性；第5 章综述了电喷雾质谱在皂苷类化合物结构鉴定中的应用进展。 第1 章报道了运用全扫描电喷雾多级质谱对两头尖中三萜皂苷类化合物的快速定性检测，共检测出18 个准分子离子峰，根据多级质谱数据并结合文献报道，对其中的15 个准分子离子峰进行了归属，并区分了一些同分异构体；更有意思的是，发现了3 个未见文献报道的三萜皂苷类化合物。根据它们的多级质谱数据，对其结构分别进行了初步解析。本章同时对银莲花素A 特殊的质谱裂解途径通过衍生物制备及其质谱分析进行了确认。 第2 和3 章，分别报道了两头尖和打破碗花花中水溶性多糖苷的分离纯化和结构鉴定。采用D101 大孔树脂和反复硅胶柱层析等分离手段，从两头尖水溶性部分分离得到8 个三萜皂苷类化合物，通过红外、电喷雾质谱和核磁共振等现代谱学方法，并结合传统的化学手段鉴定了它们的结构，其中4 个化合物为新化合物，分别命名为多被银莲花皂苷19、多被银莲花皂苷20、多被银莲花皂苷21和多被银莲花皂苷22。从打破碗花花水溶性部位分离得到6 个三萜皂苷类化合物，通过现代谱学手段，并结合传统的化学方法对它们进行了鉴定，其中1 个为新化合物，命名为打破碗花花苷H。 第4 章报道了以银莲花素A 及其同系物为先导化合物，进行化学结构修饰并对修饰产物进行广泛的生物活性筛选，发现在银莲花素A 及其同系物的结构中引入一些酸性基团后，其生物活性发生了变化，一些修饰产物显示出很强的PTP-1B 抑制作用，提示这些化合物有可能用于治疗II 型糖尿病。 第5 章综述了电喷雾多级质谱用于皂苷类化合物结构鉴定的研究进展。 This dissertation composes of five chapters. The first chapter elaborates the detection and qualification of the triterpenoidal saponins in Anemone raddeana by positive and negative full scan ESI-MSn. This part also reports the special fragmentation pathway of Raddeanin A by ESI-MS/MS. The second and third chapters present the phytochemical investigation of two medicinal plants from Anemone. The fourth part dwells on the structure modification of Raddeanin A and their inhibitory activity against PTP-1B. The last part is a review on the progress in the application of ESI-MSn in the structure identification of saponins. The first chapter reports the application of full scan ESI-MSn for fast analysis of triterpenoid saponins in Anemone raddeana. Eighteen quasi- molecular ion peaks were detected in the positive full scan ESI-MS and fifteen of them were identified by analysis of their tandem mass spectral data in the negative ion mode. Several isomers were differentiated. More interesting, three unreported triterpenoid saponins in this medicinal plant were detected and their structures were deduced according to the dissociation pathway of the known triterpenoidal saponins. This chapter also confirms the special fragmentation pathway of Raddeanin A by its derivative and the mass spectral analysis. The second and third chapters expatiate on the isolation and identification of the chemical constituents from A. raddeana and A. hupehensis. Eight compounds were isolated from the roots and stems of A. raddeana by methanol extraction and repeated column chromatography (including D101 and silica gel), and their structures were determined on the basis of IR, ESI-MS, NMR and chemical methods (including acid hydrolysis and alkaline saponification). Among them, four are new triterpenoid saponins and named as Raddeanoside R19, Raddeanoside R20, Raddeanoside R21 and Raddeanoside R22. Six compounds were isolated from the whole plants of A. hupehensis by the same methods as above, and their structures were also determined with the same way. One of them was confirmed to be new triterpenoid saponins and named as hupehensis saponin H. In the fourth chapter, in order to look for new active compounds, the structure of Raddeanin A and its analogs were modified. It was found that the modified products exhibited obvious inhibitory activity against PTP-1B when several acid groups were introduced. The fifth chapter summarizes the progress on the application of ESI-MSn in the structure identification of saponins.