固相萃取/液相色谱-质谱/质谱法测定山银花中5种主要黄酮苷元的含量

该文通过含有盐酸的乙醇溶液回流水解并提取,HLB固相萃取柱净化,液相色谱-质谱/质谱法检测,建立了山银花中槲皮素、木犀草素、山萘酚、芹菜素和黄芩素5种黄酮苷元含量的测定方法。实验以芦丁、木犀草苷、紫云英苷、野漆树苷和黄芩苷5种黄酮苷为代表开展研究,山银花样品经50%的乙醇溶液(含10%浓盐酸)回流2 h水解黄酮苷,同时对黄酮苷元进行提取,HLB固相萃取柱净化,采用Mightysil RP-18色谱柱分离,液相色谱-质谱/质谱法检测(电喷雾离子源、多反应监测模式、负离子扫描),外标法定量测定水解后的5种黄酮苷元含量。方法的定量下限(S/N=10)为0.005 g/kg(槲皮素),0.01 g/kg(木犀草素和芹菜素)和0.05 g/kg(山萘酚和黄芩素)。在0~1.0 g/kg范围内,5种黄酮苷元的线性相关系数均大于0.995;在山银花样品中对待测物进行3种加标水平的回收实验(加标水平相当于水解后槲皮素和木犀草素含量为:0.10、0.20、0.40 g/kg,山萘酚、芹菜素和黄芩素含量为:0.05、0.10、0.20 g/kg),方法的平均回收率70.4%~104%;相对标准偏差为4.0%~12%。该方法实现了山银花中多种主要黄酮苷元含量的同时测定,且对研究山银花药效及与黄酮类化合物的关系具有重要意义。     

金银花不同部位中绿原酸和木犀草苷含量的测定

利用HPLC法测定金银花不同部位中绿原酸和木犀草苷。采用ODS-C18色谱柱(250 mm×4.6 mm,5μm),以甲醇-水(0.03 mol/L磷酸)为流动相进行梯度洗脱,流速:1.0 mL/min,检测波长:350 nm,柱温:室温。绿原酸浓度在0~0.4 mg/mL内与峰面积呈良好线性关系(r2=0.999 6),回收率为101.9%~105.2%,相对标准偏差为3.18%(n=6)。木犀草苷浓度在0~0.1 mg/mL内与峰面积呈良好线性关系(r2=0.999 1),平均回收率为100.5%~104.0%,相对标准偏差为3.42%(n=6)。结果表明:金银花、芽等部位绿原酸和木犀草苷的含量较高。     

毛细管胶束电动色谱法分离测定中药半枝莲中的7种有效成分

建立了毛细管胶束电动色谱同时分析检测中药半枝莲药材及其膏剂中黄芩素、柚皮素、汉黄芩素、野黄芩苷、芹菜素、木犀草素和原儿茶酸7种有效成分的方法。半枝莲样品中7种有效成分经甲醇超声提取。实验考察了运行缓冲溶液的pH值和浓度、添加剂、检测波长、分离电压和进样时间等重要参数对目标物分离的影响。得到的优化条件为: 运行缓冲液50 mmol/L硼砂-0.20 mol/L硼酸溶液(pH 8.4),含8.5 mmol/L十二烷基硫酸钠(SDS),分离电压25 kV,检测波长260 nm和335 nm。在此条件下,7种组分于12 min内达到基线分离。各组分在8×10~6～3.2×10~4mol/L范围内呈良好的线性关系,相关系数(r2)为0.9965～0.9999;检出限为7.0×10~8～2.0×10~6mol/L;回收率均大于85%。该方法提取简便、准确可靠、重复性好、灵敏度高,可以用于中药半枝莲中7种有效成分的定量检测。     

高效液相色谱法测定野生和人工种植库鲁木提草中柚皮苷和木犀草素的含量

本文建立了新疆库鲁木提草中柚皮苷和木犀草素两种活性成分的高效液相色谱同时测定方法,并实现了野生及人工栽培库鲁木提草中柚皮苷和木犀草素的检测。采用Agilent HC-C_(18)色谱柱(250×4.6mm,5μm)分离,以甲醇-0.2%HAc水溶液作为流动相,在柱温为室温和流速1.00mL/min条件下进行梯度洗脱,实现了两种活性成分之间以及它们与干扰组分的良好分离。柚皮苷和木犀草素的线性范围分别为120~1 440mg/L(r=0.9998)和17.5~210mg/L(r=0.9999),加标回收率分别为93.8%~100.2%(RSD=1.8%~2.7%,n=3)和98.3%~100.6%(RSD=1.3%~2.9%,n=3)。研究结果表明野生库鲁木提草中柚皮苷和木犀草素的含量更高。     

等度反相高压液相色谱法同时测定艾叶中四种黄酮化合物的含量

建立艾叶中槲皮素、山萘酚、木犀草素、芹菜素含量测定方法。反相高效液相色谱法,色谱柱ZORBAX SB-C18(150×4.6 mm,5μm);检测波长360 nm;V(甲醇)∶V(0.2%H3PO4)=45∶55为流动相;柱温30℃;流速1.0 mL/min。槲皮素、山萘酚、木犀草素、芹菜素理论板数分别为槲皮素:大于5000山萘酚:大于6000木犀草素:大于6000芹菜素:大于7000;4种化合物的分离度均大于1.5。槲皮素、山萘酚、木犀草素、芹菜素回归曲线分别为:Y=1504.412X 9.9756,Y=1991.745X 8.6051,Y=567.591X 2.5397,Y=1811.803X 0.3074,在5.5216×10-2~19.3256×10-2μg/mL、4.608×10-2~16.128×10-2μg/mL、12.5504×10-2~43.9264×10-2μg/mL、6.0288×10-2~21.1008×10-2μg/mL范围内线性关系良好,相关系数r为0.99992~0.99998,加样回收率分别为102.0%、100.2%、100.1%、100.4%,RSD分别为2.97%、2.61%、2.66%、3.45%。样品分别含槲皮素、山萘酚、木犀草素、芹菜素0.754、0.841、1.629、0.79 mg/g。本法为艾叶提供了分析4种黄酮化合物方法,该法简便可行,重复性好,数据及结果可靠。     

闪式提取HPLC-DAD测定金银花中绿原酸和木犀草苷

采用闪式提取法和超声提取法分别提取金银花及其叶中的绿原酸和木犀草苷,建立HPLC-DAD分析方法进行评价,为金银花药材及相关产品的快速质量控制探索新方法。采用乙腈-1%甲酸水溶液体系经梯度洗脱,在AgilentC18色谱柱上实现了绿原酸和木犀草苷的同时基线分离,绿原酸在3.96~253.2μg/mL(326 nm,R=0.9998)、木犀草苷在0.53~34μg/mL(350 nm,R=0.9997)范围内具有良好的线性关系,方法具有良好的精密度和回收率。闪式提取3 min,金银花及其叶中绿原酸和木犀草苷的提取率均略高于超声提取法(超声3次×45 min,浸泡16 h)。组织破碎闪式提取法为金银花药材中绿原酸和木樨草苷的快速提取及质量控制提供了一种新方法。     

HPLC法同时测定忍冬叶中9种活性成分的研究

为了有效利用忍冬植株,建立了同时检测忍冬叶中新绿原酸、绿原酸、咖啡酸、芦丁、木犀草苷、金丝桃苷、异绿原酸C、木犀草素和槲皮素9种活性成分含量的HPLC分析方法,并用于忍冬叶中活性成分的定量测定,为忍冬叶多指标质量评价标准提供理论依据和方法参考.     

二维液相色谱分离及鉴定滁菊中的多酚类化合物

将Lichrospher diol-5亲水柱和Cortecs C18+反相柱组合,构建了亲水/反相二维液相色谱系统(HILIC/RPLC),理论峰容量为1 117。采用表面积覆盖法定量计算该系统分离多酚类化合物的正交性指数SCG为0.56,表明二维柱系统有着良好的峰分辨率和正交性。利用该系统对滁菊样品甲醇提取液中的多酚进行分离和鉴定,在二维空间中分离得到23个物质的色谱峰,通过对比标准样品和滁菊样品的保留时间和紫外吸收光谱,鉴定出13种多酚类物质,包括芹菜素、香叶木素、金合欢素、金合欢素-7-O-葡糖苷、绿原酸、异鼠李素-3-O-葡糖苷、香叶木素-7-O-葡糖苷、金合欢素-7-O-芸香苷、圣草酚-7-O-葡糖苷、槲皮素苷、异绿原酸A、异绿原酸B、芹菜苷。首次发现滁菊中含有异鼠李素-3-O-葡糖苷、金合欢素-7-O-芸香苷、圣草酚-7-O-葡糖苷、芹菜苷等多酚类化合物。其中,异鼠李素-3-O-葡糖苷首次发现存在于菊属植物中。     

高效液相色谱法同时测定忍冬中7种成分

建立了在不同时间段内转换使用不同波长同时测定忍冬花和叶中7种化学成分(绿原酸、咖啡酸、芦丁、木犀草苷、异绿原酸A、异绿原酸B、异绿原酸C)的高效液相色谱分析方法,同时应用该方法分析了忍冬花、忍冬老叶和新叶中成分含量的差异。色谱柱为Agilent Eclipse Plus C18(250 mm×4.6 mm, 5 μm);流动相为0.3%甲酸水溶液(A)和乙腈(B),梯度洗脱,流速1 mL/min;采用VWD紫外检测器转换波长(330 nm、350 nm)检测。应用所建立的方法测定忍冬新叶中绿原酸、木犀草苷含量分别为2.572%、1.498‰,均比药典中规定的含量高,有必要进一步的研究和开发利用。该方法准确、简便、灵敏度高,适用于忍冬中7种化学成分含量的同时测定和忍冬的质量控制及综合评价。     

微流控芯片对丹参滴注液中丹参素和原儿茶醛的测定

建立了微流控芯片非接触电导检测法测定丹参滴注液中丹参素与原儿茶醛含量的分析方法.探讨了缓冲液种类与浓度,添加剂、分离电压等因素对分离检测的影响.优化选择20 mmol/L H3BO3-20 mmol/L Tris缓冲溶液,加入1.5 mmol/L SDS添加剂,2.5 kV分离电压,3 min内可实现丹参素和原儿茶醛的快速分离检测.在优化条件下,丹参素的线性范围为10 ～500 mg/L,r为0.986,检出限为5.0 mg/L (S/N=3),RSD为2.1%;原儿茶醛的线性范围为50 ～500 mg/L,r为0.993,检出限为10 mg/L (S/N=3),RSD为2.8%.     

Microwave‐assisted extraction coupled with countercurrent chromatography for the rapid preparation of flavonoids from Scutellaria barbata D. Don

As a famous Chinese herb having good inhibitory effects on numerous human cancers both in vitro and in vivo, Scutellaria barbata D. Don attracts extensive attention worldwide. In this work, four flavonoids named scutellarin, baicalin, luteolin, and apigenin were simply and rapidly prepared from S. barbata by microwave‐assisted extraction coupled to countercurrent chromatography. Extraction conditions including irradiation time, extraction temperature, liquid/solid ratio, and microwave power were optimized using an orthogonal array design method. The extract of S. barbata was separated and purified with a two‐phase solvent system composed of hexane/ethyl acetate/methanol/acetic acid/water (1:5:1.5:1:4, v/v/v/v/v) and 4.5 mg of scutellarin, 4.6 mg of baicalin, 1.1 mg of luteolin, 2.1 mg of apigenin were obtained from 2.0 g original sample in a single run. The purities of scutellarin, baicalin, luteolin, and apigenin determined by HPLC were 93.6, 97.3, 97.6, and 98.4%, respectively. The targeted compounds were identified by LC with MS and ¹H NMR spectroscopy. The total time including extraction, separation, and purification was <300 min. Compared to traditional methods, microwave‐assisted extraction coupled to countercurrent chromatography method is more simple and rapid for the extraction, separation, and purification of flavonoid compounds from natural products.     

Phytochemical study of Centaurea cyanus

Flavonoid aglycons (quercetin, kaempferol, isorhamnetin, apigenin, luteolin, hispidulin) and their glycosides, and caffeic, chlorogenic, neochlorogenic, and isochlorogenic acids have been isolated from the epigeal part of theCentaurea cyanus L. and have been identified, and ten amino acids have also been identified.     

Phytochemical study of Centaurea cyanus

Flavonoid aglycons (quercetin, kaempferol, isorhamnetin, apigenin, luteolin, hispidulin) and their glycosides, and caffeic, chlorogenic, neochlorogenic, and isochlorogenic acids have been isolated from the epigeal part of theCentaurea cyanus L. and have been identified, and ten amino acids have also been identified.Kursk State Medical Institute. Translated from Khimiya Prirodynkh Soedinenii, No. 6, pp. 792–795, November–December, 1988.     

高效液相色谱-二极管阵列检测-电化学检测联用技术同时测定三精双黄连口服液中的4种化合物

建立了应用高效液相色谱-二极管阵列检测-电化学检测(HPLC-DAD-ECD)联用技术同时测定三精双黄连口服液中的绿原酸、咖啡酸、黄芩甙和木樨草素的方法。以Zorbax SB-C18柱(150 mm×4.6 mm i.d., 5.0 μm)为色谱柱,柱温为30 ℃，流动相为(A)甲醇和(B)甲醇-水-冰醋酸(体积比为50∶50∶1),其梯度洗脱程序为2%A3 min3%A12 min25%A5 min80%A。流速为0.8 mL/min。二极管阵列检测波长为275 nm。电化学单安培检测器的工作电压为0.7 V。在上述条件下实现了绿原酸、咖啡酸、黄芩甙和木樨草素的分离检测。上述4种化合物的回收率为96.6%～99.6%,相对标准偏差(RSD)为2.5%～4.1%,检测限依次为1,0.2,9和7 mg/L。该方法简便、快速,重现性和准确度较好,可作为测定双黄连口服液中绿原酸、咖啡酸、黄芩甙和木樨草素的有效方法。     

银黄冲剂中黄芩甙和绿原酸的毛细管电泳分离分析

摘要：用毛细管电泳法分离并测定了银黄冲剂中黄芩甙和绿原酸。以对硝基苯甲酸为内标,未涂层融硅毛细管（50μmi.d.,370μmo.d.,总长47cm,有效分离长度40cm）为分离通道,25mmol/L硼砂缓冲液（pH8.5）为电泳介质,17kPa·s压力进样,25kV恒压电泳,310nm检测。黄芩甙和绿原酸线性范围分别为160～960mg/L(r=0.9993,RSD=1.76％～2.33％）和80～960mg/L（r=0.9989,RSD=1.07％～2.51％）,加入回收率：黄芩甙为（102.09±1     

超滤亲和结合液相色谱-质谱联用和分子对接技术筛选毛菊苣种子中高亲和性α-葡萄糖苷酶抑制剂

采用超滤亲和结合液相色谱-质谱联用(UF-LC-MS) 和分子对接技术筛选毛菊苣种子中高亲和α-葡萄糖苷酶抑制剂.以4-硝基苯-α-D-吡喃葡萄糖苷(PNPG)为底物,阿卡波糖为阳性对照,评价毛菊苣种子提取物对α-葡萄糖苷酶的抑制活性,其中阿卡波糖IC50为0.003 mg/mL,毛菊苣种子IC50为0.447 mg/mL.利用UF-LC-MS技术对毛菊苣种子提取物进行筛选鉴定,获得4种化合物;通过Autodock软件筛选出2种与α-葡萄糖苷酶有较高亲和力的化合物,分别是绿原酸和异绿原酸A.结合体外酶活实验,验证了绿原酸、异绿原酸A对α-葡萄糖苷酶的抑制活性.结果表明,各化合物对α-葡萄糖苷酶的抑制活性由大到小依次是:阿卡波糖>异绿原酸A>绿原酸,其中异绿原酸A与阿卡波糖抑制率相近.     

Retention behavior of silica-bonded and novel polymeric reversed-phase sorbents in studies on flavones as chemotaxonomic markers of Scutellaria L. genus

In this study, the effectiveness of both classical and novel polymeric sorbents used in solid-phase extraction (SPE) for isolation of pharmacologically active flavones (baicalin, luteolin, apigenin, wogonin and chrysin) from aerial parts of 13 species of Scutellaria L. (Skullcap) genus was assessed. The highest recoveries of hydrophilic (baicalin, luteolin) flavones for Oasis HLB were obtained, whereas for medium hydrophobic (apigenin) and hydrophobic (wogonin, chrysin) flavones better quantitative results for BakerBond phenyl cartridges were stated. Eluates were analysed using reversed-phase high-performance liquid chromatography with diode array detection (RP-HPLC-DAD). For the five target compounds the determined concentrations ranged from approximately 4 to approximately 15,500 microg/g dry wt. Very good linearities (r(2)>0.9995) of calibration curves were achieved for each flavone. The accuracy was below 5% for most compounds examined. This is the first method reported that enabled simultaneous qualification and quantitation of five flavones (being chemotaxonomic markers) in 13 species of Scutellaria L. genus.     

Capillary electrochromatography of selected phenolic compounds of Chamomilla recutita

This article explores the use of capillary electrochromatography for the analysis of chamomile (Chamomilla recutita L.) extracts. After a thorough study of analytical parameters such as mobile and stationary phase composition, applied voltage, and temperature, a methodology to determine 11 bioactive phenolic compounds (coumarins: herniarin, umbelliferone; phenylpropanoids: chlorogenic acid, caffeic acid; flavones: apigenin, apigenin-7-O-glucoside, luteolin, luteolin-7-O-glucoside; flavonols: quercetin, rutin and flavanone: naringenin) in chamomile extracts was proposed. The method was performed in a Hypersil SCX/C18 column with pH 2.8 phosphate buffer at 50 mmol L(-1) containing 50% acetonitrile (pH adjusted before the addition of the organic solvent). All compounds were separated in less than 7.5 min under isocratic conditions. Figures of merit include linearity (peak area versus apigenin concentration) from 50.0-1000 microg/mL (r2=0.995), and intra-day precision of retention time and peak area better than 1.3% CV and 15%, respectively. The limits of detection and quantification for apigenin were 35.0 microg/mL and 150.0 microg/mL, respectively. This article also describes an NMR 1H study, carried out to monitor a new clean-up procedure for extracts containing propyleneglycol, whose components are poorly retained in conventional octadecyl silica cartridges.