HPLC-DAD法测定血满草中熊果酸和齐墩果酸的含量(英文)

建立了HPLC-DAD法测定血满草中熊果酸和齐墩果酸含量,并进行方法学考察。采用HPLC-DAD进行分析,fusion-RP C18柱(4.6 mm×250 mm,4μm),甲醇-0.2%磷酸水溶液(90∶10)为流动相,检测波长210 nm,体积流量1.0 mL/min。同时采用微波辅助提取、回流提取、索氏提取、冷浸提取、超声提取五种方法对血满草中熊果酸和齐墩果酸含量进行测定并比较不同方法所得结果的差异,还比较了血满草不同部位中熊果酸和齐墩果酸的含量差异。测定结果表明熊果酸进样量在3.6～8.4μg范围内,齐墩果酸进样量在3.2～16μg范围内,呈良好线性关系。血满草中熊果酸和齐墩果酸平均回收率分别为98.3%和101.4%(n=5),相对标准偏差分别为1.13%和0.72%(n=5)。五种方法比较得出索氏提取得熊果酸和齐墩果酸含量最高;血满草花中熊果酸和齐墩果酸含量最高,而根中含量最低。该方法使血满草中熊果酸和齐墩果酸达到基线分离,操作简便,结果稳定可靠。     

HPLC法测定植物中乌索酸的含量

采用HPLC法测定6种植物中乌索酸的含量,为扩大植物中乌索酸药物资源的开发利用提供分离测定方法。色谱柱为SyrmnetryShieldRP18,流动相甲醇-水-磷酸(88：12：0．1),流速1．0mL／min,检测波长210m,柱温2．5℃。该方法的线性范围为0．192-3．072μg,R=0．9999,平均回收率为98．12％,RSD=1．7％(n=5)。HPLC法测定乌索酸含量灵敏、准确、重现性好。     

一种测定女贞子中齐墩果酸和熊果酸的新方法

为建立一种加速溶剂萃取-毛细管区带电泳测定女贞子中齐墩果酸和熊果酸的新方法.考察了萃取温度、萃取时间和萃取次数对目标物萃取效率的影响,并考察了硼砂浓度,β-环糊精浓度、pH及甲醇浓度对目标物分离的影响.结果表明:(1)萃取温度和萃取次数影响目标物的萃取效率,而萃取时间的影响很小;萃取压力影响萃取过程的重现性.(2)优化的萃取条件为:萃取压力6.9 MPa,萃取温度100℃,萃取时间5 min和萃取次数2次.(3)优化的缓冲体系为:40 mmol/L硼砂,1 mmol/Lβ-环糊精,pH 9.5及6%甲醇.(4)齐墩果酸和熊果酸分别在10~200、10~160 mg/L范围内线性良好,相关系数均大于0.996,检测限分别为3.2 mg/L和3.0 mg/L,加标回收率为93%~97%.对比了加速溶剂萃取、索氏提取以及超声提取的提取效率.(5)不同提取方法比较结果表明,加速溶剂萃取的提取效率与索氏提取法接近,但高于超声提取;加速溶剂萃取法的主要优点是消耗提取溶剂量少,提取时间短,样品用量小.     

冬凌草离体培养体系的建立及主要次生代谢产物的测定

以冬凌草叶片为外植体,研究不同浓度激素组合对冬凌草愈伤组织诱导及植株再生的影响,并对不同外植体(茎、叶)诱导愈伤、芽的分化能力及再生植株内主要次生代谢产物的含量进行了比较研究。结果表明:在MS 2.0 mg/L 6-BA 1.0 mg/L NAA培养基上诱导愈伤组织效果较好;在MS 2.0 mg/L 6-BA的培养基上诱导芽的效果较好;叶片和茎段在愈伤诱导培养基上均能产生大量的愈伤组织,但其再分化能力以茎段最好;再生苗生根培养基以0.3 mg/L IBA最好;以叶为外植体诱导的再生植株中冬凌草甲素、迷迭香酸的含量均高于以茎为外植体诱导的再生植株。     

高效液相色谱法测定山楂叶中熊果酸含量的研究

本文建立了一种可靠性高、重现性好的高效液相色谱(HPLC)测定山楂叶中熊果酸含量的方法,在测定中采用富集和固相萃取组合纯化工艺去除干扰物质。高效液相色谱测定条件为Hypersil(ODS)色谱柱,流动相为甲醇:0.2%磷酸二氢钠(90∶10,V/V),检测波长210nm,流速0.8mL/min。熊果酸浓度在100~800μg/mL与峰面积存在良好线性关系(r2=0.9992),该方法准确可靠,日内稳定性标准偏差在0.6%~1.5%,日间稳定性标准偏差在0.7%~2.6%。为不同产地山楂叶中熊果酸含量建立有效的分析方法。     

反相高效液相色谱法测定不同采收期柿叶芦丁、齐墩果酸的含量

研究柿叶中芦丁、齐墩果酸随月份动态变化规律。用回流提取法制备同一来源、不同月份柿叶样品,采用RP-HPLC法,以芦丁为对照品,测定同一年中5月到11月7份样品中芦丁的含量。用索氏提取法制备不同月份柿叶齐墩果酸样品,采用RP-HPLC,以齐墩果酸为对照品,测定同一年中5月到11月7份样品中齐墩果酸的含量。结果显示:7月和10月采收的柿叶中芦丁和齐墩果酸的含量较高。10月(采收柿子果实后)采收的柿叶有可能作为制备芦丁、齐墩果酸的原料使用。     

Simultaneous Enantioseparation of Aldohexoses and Aldopentoses Derivatized With L‐Tryptophanamide by Reversed Phase HPLC Using Butylboronic Acid as a Complexation Reagent of Monosaccharides

Three aldohexoses, glucose, galactose, and mannose, and three aldopentoses, arabinose, xylose, and ribose, were derivatized with L‐tryptophanamide (L‐TrpNH₂) under alkaline conditions. Using a basic mobile phase (pH 9.2), the three aldohexoses or the three aldopentoses were simultaneously enantioseparated, respectively, but all the six monosaccharides could not be simultaneously enantioseparated. A large amount of nonreacted L‐TrpNH₂ was detected after the derivatized monosaccharides. In order to widen the separation window, a large portion of nonreacted L‐TrpNH₂ could be eliminated by liquid–liquid extraction with ethylacetate, and elution order of the derivatized monosaccharides and nonreacted L‐TrpNH₂ was found to be reversed using a neutral mobile phase. All of the six monosaccharides were simultaneously enantioseparated by reversed phase high‐performance liquid chromatography (HPLC) using InertSustainSwift C18 column (4.6 mm i.d. × 150 mm) and a mobile phase containing 180 mM phosphate buffer (pH 7.6), 1.5 mM butylboronic acid, and 5% acetonitrile at 40 °C. Nomenclature of D and L for monosaccharides is based on the configurations of the asymmetric C4 center for aldopentoses and C5 center for aldohexoses. It was found that the enantiomer elution order of these six monosaccharides and fucose in the proposed method conformed to be the absolute configuration of the C2 center. Chirality 27:417–421, 2015. © 2015 Wiley Periodicals, Inc.     

Trifluoroethanol‐containing RP‐HPLC mobile phases for the separation of transmembrane peptides human glycophorin‐A,integrin alpha‐1, and p24: analysis and prevention of potential side reactions due to formic acid

Reversed‐phase high‐pressure liquid chromatography analysis and purification of three hydrophobic, aggregation‐prone peptides, composed mainly of the transmembrane (TM) sequence, were performed using elution systems containing 2,2,2‐trifluoroethanol (TFE). The addition of 10–16% TFE to a common mobile phase, such as a water/acetonitrile/propanol (PrOH) or a water/PrOH/formic acid system, markedly improved the chromatographic separation of these peptides. The superior performance of TFE‐containing systems in separating peptides over water/PrOH/formic acid systems [Bollhagen R. et al., J. Chromatogr. A, 1995; 711 : 181–186.] clearly demonstrated that adding TFE to the mobile phase is one of best methods for TM‐peptide purification. Characterization of the potential side reactions using MALDI and ESI‐LIT/Orbitrap mass spectrometry indicated that prolonged incubation of peptides in a mixture of TFE–formic acid possibly induces O‐formylation of the Ser residue and N‐formylation of the N‐terminus of peptides. The conditions for selective removal of the formyl groups from TM peptides were also screened. We believe that these results will expand our ability to analyze and prepare hydrophobic, aggregation‐prone TM peptides and proteins. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Simultaneous Enantiomeric Determination of Propranolol,Metoprolol, Pindolol,and Atenolol in Natural Waters by HPLC on New Polysaccharide‐Based Stationary Phase using a Highly Selective Molecularly Imprinted Polymer Extraction

A simple high performance liquid chromatography method HPLC‐UV for simultaneous enantiomeric determination of propranolol, metoprolol, pindolol, and atenolol in natural water samples was developed and validated, using a molecularly imprinted polymer solid‐phase extraction. To achieve this purpose, Lux® Cellulose‐1/Sepapak‐1 (cellulose tris‐(3,5‐dymethylphenylcarbamate)) (Phenomenex, Madrid, Spain) chiral stationary phase was used in gradient elution and normal phase mode at ambient temperature. The gradient elution program optimized consisted of a progressive change of the mobile phase polarity from n‐hex/EtOH/DEA 90/10/0.5 (v/v/v) to 60/40/0.5 (v/v/v) in 13 min, delivered at a flow rate of 1.3 ml/min and a sudden change of flow rate to 2.3 ml/min in 1 min. Critical steps in any molecularly imprinted polymer extraction protocol such as the flow rate to load the water sample in the cartridges and the breakthrough volume were optimized to obtain the higher extraction recoveries for all compounds. In optimal conditions (100 ml breakthrough volume loaded at 2.0 ml/min), extraction recoveries for the four pairs of β‐blockers were near 100%. The MIP‐SPE‐HPLC‐UV method developed demonstrates good linearity (R² ≥ 0.99), precision, selectivity, and sensitivity. Method limit detection was 3.0 µg/l for propranolol and pindolol enantiomers and 20.0 and 22.0 µg/l for metoprolol and atenolol enantiomers, respectively. The proposed methodology should be suitable for routine control of these emerging pollutants in natural waters for a better understanding of the environmental impact and fate. Chirality 24:860–866, 2012. © 2012 Wiley Periodicals, Inc.