HPLC法测定野生与栽培藏药麻花艽中4种环烯醚萜苷类成分的含量

目的：对野生和栽培藏药麻花艽中龙胆苦苷、落干酸、獐牙菜苦苷和獐牙菜苷4种苦苷类成分进行高效液相色谱的含量测定，并比较分析它们之间的差异。方法：采用Eelipse XDB-C_8色潜柱(4.6 mm*150 mm，5 μm)，流动相A为95％乙腈水溶液，B为5％乙腈(含10 mmol•L~(-1)的甲酸)水溶液，A在0-20min内比例由0-100％进行线性洗脱，流速1.0 mL•min~(-1)，检测波长240 nm，柱温30℃。结果：4种成分均达到基线分离，龙胆菁苷、落干酸、獐牙菜苦苷、獐牙菜苷的线性范围分别为0.60～19•20μg(r=0.9999)，0.24～7.68μg(r=O.9999)，0.38-12.02μg(r=O.9999)，0.05～1.66μg(r=0.9999)；回收率分别为99.73％，98.13％，98.45％，96.22％。结论：栽培藏药麻花艽中苦苷类成分的含量已经接近或超过野生种的水平，可初步代替野生药材人药。

唐古特白刺籽油的超临界CO_2流体萃取及GC／MS分析

利用超临界CO_2萃取唐古特白刺籽油，并对籽油进行了GC／MS分析。实验确定的最佳超临界CO_2流体萃取条件是:萃取温度45℃，萃取压力20 MPa，CO_2流量为35-40 kg／h，萃取时间120min，在此条件下白刺籽油的萃取率为15.11％。利用GC／MS对白刺籽油分析，发现其不饱和脂肪酸的相对含量高达93.37％。比较了超临界CO_2萃取白刺籽油油样和石油醚萃取白刺籽油油样的理化性质，发现超临界CO_2流体萃取的籽油质量优于传统溶剂萃取的籽油。

HPLC测定刺芒龙胆不同部位中3种有效成分的含量

目的：建立反相高效液相色谱法同时测定刺芒龙胆植物不同部位落干酸、獐牙菜苦苷、龙胆苦苷的含量。方法：采用ZORBAX SB-C18（250mm×4．6mm，5μm）色谱柱，流动相为甲醇-水（含0．04％磷酸）的比例25：75，流速1mL·min^-1，检测波长238nm，柱温30℃。结果：3种成分均达到基线分离，落干酸、獐牙莱苦苷、龙胆苦苷的线性范围分别为0．039～1．56μg（r=0．9998），0．0725～1．45μg（r=0．9999），0．061～1．225μg（r=0．9997）；回收率为101．3％（RSD=2．6％），98．7％（RSD=3．1％，99．6％（RSD=1．2％）。结论：测定方法快速，结果准确、可靠。

高效液相色谱／质谱分析抱茎獐牙菜提取物中的苷性成分

采用高效液相色谱／质谱法（HPLC／MS）分析抱茎獐牙菜提取物中5种苷性成分。在C18柱上，以甲醇（A：含20％水）和水（B：含10％甲醇）为流动相，流速1mL／min，线性梯度洗脱B从100％到0％，35min，液相色谱-质谱质联用（LC／MS），大气压化学电离源（APCI），对其中5种苷性成分进行定性鉴定。经HPLC／APCIMS分析确证，抱茎獐牙菜提取物中含有獐牙菜苦苷（swertiamarin）、龙胆苦苷（gentiopicroside）、獐牙菜苷（sweroside）、异红草苷（isoorientin）和獐牙菜山酮苷（swertianolin）。采用外标法定量，回收率分别为98．3％、106．7％、92．3％、88．2％和107．3％，该方法简便、快速、准确。

SPE-HPLC法测定藏药能安均宁胶囊中胡椒碱的含量

目的建立能安均宁胶囊(主要由北寒水石,石榴子,荜茇等组成)中胡椒碱含量的测定方法.方法采用SPE-HPLC法,使用Kromasil C18柱,胡椒碱流动相为甲醇-水(77∶23);检测波长为343nm.结果胡椒碱平均回收率为99.07%,RSD%=2.43%(n=3).结论该方法简便、准确、重现性好,可以用作能安均宁胶囊质量控制.

西藏产两种岩白菜中岩白菜素的HPLC测定

建立测定了岩白菜中岩白菜素含量的方法.色谱柱:Waters C18柱(5 μm×3.9 mm×150 mm),流动相:甲醇∶水∶磷酸=20∶80∶0.1,流速为1.0 mL/min,检测波长275 nm,AUFS 0.01,柱温为室温.结果表明,岩白菜素在0.16～0.08 μg有良好线性关系,r=0.999 2,平均回收率为98.14%,RSD为1.12%.本方法是测定岩白菜中岩白菜素含量的快速、简便、准确可靠的定量方法.

HPLC法测定獐牙菜及其近缘植物中4种有效成分的含量

目的:建立反相高效液相色谱法同时测定獐牙菜及其近缘植物中番木鳖酸、獐牙菜苦苷、龙胆苦苷、芒果苷的含量。方法:采用ZORBAX SB—C18(250 mm×4.6mm,5μm)色谱柱,以流动相甲醇和水(含0.04%磷酸)的比例在0-24 min内由22:78至38:62线性梯度洗脱,流速1 mL•min～1,检测波长254 nm,柱温30℃。结果:4种成分均达到基线分离,番木鳖酸、獐牙菜苦苷、龙胆苦苷、芒果苷的线性范围分别为0.05—6.25μg(r=0.9999),0.0095—2.9 μg(r=0.9998),0.0486—2.56μg(r=0.9999),0.0056—2.8μg(r=0.9998);回收率为102%(RSD=4.4%),97.7%(RSD=4.3%),99.5%(RSD=3.5%),103%(RSD=1.1%)。结论:方法测定快速,结果准确、可靠。

藏药秦艽、麻花艽中落干酸和龙胆苦甙的HPLC法含量测定

应用反相高效液相色谱法同时测定藏药秦艽、麻花艽中落干酸、龙胆苦甙含量.并比较了加热回流提取及超声提取两种方法对分析结果的影响.还测定了两种藏药全草及根、茎、叶、花等不同部位两种成分的含量.

藏药抱茎獐牙莱HPLC指纹图谱研究

采用反相高效液相色谱-二极管阵列的检测方法,对不同产地的10批野生和栽培抱茎獐牙菜药材的水溶性成分进行了分析,建立了抱茎獐牙菜药材的指纹图谱.色谱柱为VP-ODS C18柱(5 μm,150 mm×4.6 mm),流动相为甲醇-0.02%的磷酸水溶液,检测波长254 nm.用文中的最佳条件可较全面地反映抱茎獐牙菜的主要成分,为藏药抱茎獐牙菜的质量控制提供了科学依据.

HPLC法测定麻黄及其两种制剂中麻黄碱的含量

麻黄为常用中药,其中含有多种有机胺类生物碱,主要成分为L-麻黄碱、D-麻黄碱,具有松弛平滑肌、收缩血管、抗炎、兴奋中枢等作用[1],但如果用量过大或长期使用,会产生震颤、焦虑失眠、心悸等副作用,其含量常作为评价药材品质及其复方制剂质量标准的主要指标[2].麻杏石甘丸和鹏力止鼾颗粒均是以麻黄为主要原料的复方制剂,因此对其进行含量测定是控制麻杏石甘丸和鹏力止鼾颗粒质量的关键.目前国内外学者对麻黄中麻黄碱含量的测定报道较多[3,4],本文采用HPLC法测定其中的麻黄碱含量,现将结果报道如下。

青藏高原红景天药材的HPLC指纹图谱

利用高效液相色谱法建立了青藏高原红景天的色谱指纹图谱.固定相采用C18反相色谱柱,流动相为甲醇:0.1%磷酸水(v/v＝15:85);检测波长220 nm;流速为1.0 mL/min.通过比较发现红景天样品的8个主要共有峰,可作为鉴别红景天药材的主要依据.方法简便快速,为中药品种的鉴定提供了较全面的信息.

高寒藏药--抱茎獐牙菜组织培养研究及其愈伤组织有效成分的测定

从抱茎獐牙菜的胚轴、幼叶及未成熟种子诱导出愈伤组织并再生植株,试验选用MS、B5 和N6 三种培养基,其中以附加2. 4 - D3. 0mg/ L + 6 - BA0. 5mg/ L的MS 培养基诱导率最高;以附加6 - BA0. 5mg/ L + NAA 0. 2mg/ L 的MS 培养基分化苗频率最高;以附加2. 4 - D2. 0mg/ L + 6 - BA0. 5mg/ L 的MS 培养基愈伤组织的生长最好。结果表明,外植体,培养基,激素等对愈伤组织诱导、继代和分化均有明显影响。采用高压液相色谱法(HPLC) 测定抱茎獐牙菜愈伤组织中齐墩果酸含量的结果表明,愈伤组织中齐果墩酸含量因培养基、继代培养时间的不同而有所差异。

Simultaneous determination of monoamine and amino acid neurotransmitters in rat endbrain tissues by pre-column derivatization with high-performance liquid chromatographic fluorescence detection and mass spectrometric identification

A sensitive and efficient method for simultaneous determination of glutamic acid (Glu), gamma-amino-butyric acid (GABA), dopamine (DA), 5-hydroxytryptamine (5-HT) and 5-hydroxyindole acetic acid (5-HIAA) in rat endbrains was developed by high-performance liquid chromatography (HPLC) with fluorescence detection and on-line mass spectrometric identification following derivatization with 1,2-benzo-3,4-dihydrocarbazole-9-ethyl chloroformate (BCEOC). Different parameters which influenced derivatization and separation were optimized. The complete separation of five neurotransmitter (NT) derivatives was performed on a reversed-phase Hypersil BDS-C-18 column with a gradient elution. The rapid structure identification of five neurotransmitter derivatives was carried out by on-line mass spectrometry with electrospray ionization (ESI) source in positive ion mode, and the BCEOC-labeled derivatives were characterized by easy-to-interpret mass spectra. Stability of derivatives, repeatability, precision and accuracy were evaluated and the results were excellent for efficient HPLC analysis. The quantitative linear range of five neurotransmitters were 2.441-2 x 10(4) nM, and limits of detection were in the range of 0.398-1.258 nM (S/N = 3:1). The changes of their concentrations in endbrains of three rat groups were also studied using this HPLC fluorescence detection method. The results indicated that exhausting exercise could obviously influence the concentrations of neurotransmitters in rat endbrains. The established method exhibited excellent validity, high sensitivity and convenience, and provided a new technique for simultaneous analysis of monoamine and amino acid neurotransmitters in rat brain. (C) 2008 Elsevier B.V. All rights reserved.

Mass spectrometric identification of multihydroxy phenolic compounds in Tibetan herbal medicines

A highly selective and accurate method based on derivatization with dansyl chloride coupled with liquid chromatography-mass spectrometry has been developed for identification of natural pharmacologically active phenolic compounds in extracts of Lomatogonium rotatum plants (Tibetan herbal medicine) obtained by solid-phase extraction. The number of hydroxyl groups on the dansylated phenols was estimated by LC-MS-MS analysis in positive-ion mode. Dansyl derivatization of the compounds introduced basic secondary nitrogen into the phenolic core structures and this was readily ionized when acidic HPLC mobile phases were used. MS fragmentation of the derivatives generated intense protonated molecular ions of m/z [MH](+) (phenol aglycones were transformed into the corresponding free phenols by cleavage of an aglycone bond). Collision-induced dissociation of the protonated molecule generated characteristic product ions of m/z 234 and 171 corresponding to the protonated 5-(dimethylamino)naphthalene sulfoxide and 5 -(dimethylamino) naphthalene moieties, respectively. Selected reaction monitoring based on the m/z [MH](+) to 234 and 171 transitions was highly specific for these phenolic compounds. Characteristic ions with m/z values of [MH - 234](+), [MH 2 x 234](+), and [MH - 3 x 234](+) were of great importance for estimation of the presence of multihydroxyl groups on the phenolic backbone.

Study of a new derivatizing reagent that improves the analysis of amino acids by HPLC with fluorescence detection: application to hydrolyzed rape bee pollen

A simple and sensitive method for evaluating the chemical compositions of protein amino acids, including cystine (Cys)(2) and tryptophane (Try) has been developed, based on the use of a sensitive labeling reagent 2-(11H-benzo[alpha]-carbazol-11-yl) ethyl chloroformate (BCEC-Cl) along with fluorescence detection. The chromophore of the 1,2-benzo-3,4-dihydrocarbazole-ethyl chloroformate (BCEOC-Cl) molecule was replaced with the 2-(11H-benzo[alpha]-carbazol-11-yl) ethyl functional group, yielding the sensitive fluorescence molecule BCEC-Cl. The new reagent BCEC-Cl could then be substituted for labeling reagents commonly used in amino acid derivatization. The BCEC-amino acid derivatives exhibited very high detection sensitivities, particularly in the cases of (Cys)(2) and Try, which cannot be determined using traditional labeling reagents such as 9-fluorenyl methylchloroformate (FMOC-Cl) and ortho-phthaldialdehyde (OPA). The fluorescence detection intensities for the BCEC derivatives were compared to those obtained when using FMOC-Cl and BCEOC-Cl as labeling reagents. The ratios I (BCEC)/I (BCEOC) = 1.17-3.57, I (BCEC)/I (FMOC) = 1.13-8.21, and UVBCEC/UVBCEOC = 1.67-4.90 (where I is the fluorescence intensity and UV is the ultraviolet absorbance). Derivative separation was optimized on a Hypersil BDS C-18 column. The detection limits calculated from 1.0 pmol injections, at a signal-to-noise ratio of 3, ranged from 7.2 fmol for Try to 8.4 fmol for (Cys)(2). Excellent linear responses were observed, with coefficients of > 0.9994. When coupled with high-performance liquid chromatography, the method established here allowed the development of a highly sensitive and specific method for the quantitative analysis of trace levels of amino acids including (Cys)(2) and Try from bee-collected pollen (bee pollen) samples.