鸢尾苷对透明质酸酶抑制作用的研究

以射干中提取分离所得的鸢尾苷为透明质酸酶(HAase)抑制剂,采用Elson-Morgan改良法测定鸢尾苷对HAase的抑制作用,并用荧光光谱法研究鸢尾苷对HAase的作用机制。研究结果表明,鸢尾苷对HAase有明显的抑制作用,抑制率达到81.2%;鸢尾苷对HAase具有荧光猝灭作用,猝灭方式为静态猝灭。     

高效液相色谱-电喷雾质谱法测定红车轴草中异黄酮类化合物

采用高效液相色谱与电喷雾质谱联用技术研究了红车轴草中的异黄酮类化合物.实验采用反相C18色谱柱,二元线性梯度洗脱,分离并检测了红车轴草中的14种异黄酮类化合物;通过与电喷雾质谱联用获得了相应化合物的分子量信息,并利用质谱的源内碰撞诱导解离技术鉴定这些化合物的可能结构分别为大豆苷、野靛苷-7-O-β-D-葡萄糖苷、芒柄花苷、德鸢尾素-4'-O-β-D-葡萄糖苷、大豆苷元、印度黄檀苷、樱黄素-4'-O-β-D-葡萄糖苷、染料木素、红车轴草素、芒柄花素、樱黄素、鹰嘴豆芽素A、野靛苷和德鸢尾素.     

高效液相色谱-电喷雾质谱法测定红车轴草中异黄酮类化合物

采用高效液相色谱与电喷雾质谱联用技术研究了红车轴草中的异黄酮类化合物。实验采用反相C18色谱柱，二元线性梯度洗脱，分离并检测了红车轴草中的14种异黄酮类化合物；通过与电喷雾质谱联用获得了相应化合物的分子量信息，并利用质谱的源内碰撞诱导解离技术鉴定这些化合物的可能结构分别为：大豆苷、野靛苷-7-O-β-D-葡萄糖苷、芒柄花苷、德鸢尾素-4＇-O-β-D-葡萄糖苷、大豆苷元、印度黄檀苷、樱黄素-4＇-O-β-D-葡萄糖苷、染料木素、红车轴草素、芒柄花素、樱黄素、鹰嘴豆芽素A、野靛苷和德鸢尾素。     

高效毛细管电泳同时分离测定栀子苷、芍药苷及丹皮酚的研究

建立了同时分离测定栀子苷、芍药苷和丹皮酚的高效毛细管电泳新方法.以十六烷基三甲基溴化铵为表面活性剂形成胶束、甲醇作为有机改性剂、 NaOH溶液为背景电解质,在234 nm 波长下紫外检测.对十六烷基三甲基溴化铵、 NaOH的浓度以及有机改性剂、分离电压等因素对分离的影响做了系统的研究, 确立了栀子苷、芍药苷和丹皮酚的最佳分离条件.栀子苷、芍药苷、丹皮酚分别在20～100 μg/mL,5～80 μg/mL,2～20 μg/mL范围内呈较好的线性关系,回收率分别为99.00%～100.27%,99.49%～101.83%,97.11%～99.06%.方法已用于加味逍遥丸中3种成分的检测.     

羟丙基-β-环糊精富集提取射干中异黄酮

利用羟丙基-β-环糊精（HP-β-CD）水溶液对中药射干（Belamcanda chinensis）中功能性成分异黄酮类物质富集提取。 考察了时间、温度等对提取效果的影响,确定了优化的工艺条件;结合紫外光谱、高效液相色谱和液相色谱-质谱联用等检测手段,测定提取源总异黄酮含量及黄酮种类。 在此条件下,对异黄酮类物质的提取总量较纯水浸取提高1倍,鸢尾苷提取量可提高2倍。     

毛细管电泳安培检测法测定密蒙花中的黄酮类化合物

采用毛细管电泳-安培检测法(CE-AD)对蒙花苷、刺槐素、木犀草素和芹黄素四种黄酮类化合物进行分离分析.在电极电位为+0.95 V(vs.Ag/AgCl),电泳运行液为pH=9.00的60 mmol/L Na2 B4O7-120 mmol/L NaH2 PO4缓冲溶液,分离电压为18kV时,四种黄酮类化合物得到完全分离...     

毛细管电泳法测定石榴皮中鞣花酸与安石榴苷含量

建立了毛细管电泳紫外检测法测定石榴皮中鞣花酸和安石榴苷含量的方法,并对不同产地石榴中的石榴皮鞣花酸和安石榴苷含量进行测定。研究了运行缓冲液pH值和浓度、运行电压等对电泳的影响,得到最优化的测定条件为:50 mmol/L的硼砂-硼酸缓冲液(pH 8.7),分离电压20 kV,电动进样9 s/20 kV。在最优条件下,检测波长260 nm,上述两种组分可在12 min内完全分离。结果显示,鞣花酸和安石榴苷的线性范围分别为5.0×10-7～5.0×10-5g/mL和2.0×10-6～5.0×10-5g/mL,检出限分别为1.0×10-7g/mL和1.3×10-6g/mL,峰面积的相对标准偏差(RSD,n=7)分别为2.4%和2.2%,平均回收率分别为101%和98%。采用高效液相色谱法进行比对,t-检验表明两组数据无显著性差异。该法简便、快速、准确,已成功应用于实际样品的测定。     

乙醛酸和草酸的毛细管区带电泳分析

建立了同时测定乙醛酸和草酸的毛细管区带电泳法。考察了缓冲溶液的种类、浓度和pH以及分离电压等因素对分离结果的影响。在缓冲溶液为20 mmol/L硼砂-5.5 mmol/L邻苯二甲酸氢钾(pH 9.0)、分离电压20 kV、检测波长212 nm的优化条件下,11 min内即可实现对目标物的分离。乙醛酸和草酸分别在0.8～20 g/L和1.2～20 g/L范围内线性关系良好,相关系数分别为0.9993和0.9975;方法的检出限分别为0.2和0.4 g/L(信噪比为3);样品的加标回收率为98.3%～102.5%,相对标准偏差为0.35%～0.61%。该方法操作简便、快速、成本低廉,已应用于实际样品的分析,并获得了令人满意的结果。     

人尿中异黄酮的高效液相色谱分析

建立了测定人尿中异黄酮组分(大豆苷原、黄豆黄素、雌马酚、染料木黄酮)含量的反相高效液相色谱法。在尿样中加入黄酮作为内标,异黄酮经酶解后在pH=7.0中性条件下用乙酸乙酯(1∶1)提取,然后用0.02%TFA-M eOH-ACN三元梯度洗脱的方法分离异黄酮。在该条件下,大豆苷原、黄豆黄素、雌马酚、染料木黄酮的检出限分别为12.9 nmol/L、13.9 nmol/L、71.6 nmol/L和11.8 nmol/L;回收率均在89%以上。本方法具有测试步骤简单、准确度高、重现性好等优点,适合大批量样品测定。     

TLC-HPLC-Q-TOF-MS法快速鉴定柑橘提取物消毒液中桔皮素、蜜橘黄素、新橙皮苷和柚皮苷及其含量测定

建立了薄层色谱-高效液相色谱-四极杆飞行时间质谱法联用技术(TLC-HPLC-QTOF-MS)快速鉴定柑橘提取物消毒液中桔皮素、蜜橘黄素、新橙皮苷和柚皮苷4种活性物质并测定其含量的方法。样品经氯仿-丙酮洗脱剂梯度洗脱,TLC检识,半制备HPLC纯化,HPLCMS/MS鉴定及HPLC含量测定。结果表明,以氯仿-丙酮(3:1,V/V)作为展开剂分离效果最好。以甲醇-水(7:3,V/V)作为流动相测定桔皮素和蜜橘黄素的含量,以甲醇-0.2%乙酸(13:7,V/V)作为流动相对柚皮苷和新橙皮苷进行定性和定量分析,分离度及峰形最佳。方法测定桔皮素、蜜橘黄素、新橙皮苷和柚皮苷含量的相关系数均大于0.999,检测限分别为:0.3,0.1,0.4,1.2μg/mL,相对标准偏差分别为1.9%,1.9%,2.2%,1.5%,平均回收率分别为97.0%,103.5%,97.8%,100.1%。方法可用于柑橘提取物消毒液质量控制。     

尿液中麻黄碱与可待因的扫集胶束电动色谱法快速测定

采用扫集胶束毛细管电泳,建立了快速测定尿液中麻黄碱和可待因含量的方法,并通过日内、日间实验对方法的稳定性进行考察。讨论了pH值、十二烷基硫酸钠（SDS）浓度、分离电压、进样时间等因素的影响。建立了扫集胶束电动色谱的最佳实验条件,其中pH 2.2缓冲体系含80 mmol/L SDS,20 mmol/LNaH2PO4,18%（体积分数）乙腈,分离电压-20 kV,测量波长200 nm。在优化条件下,麻黄碱和可待因均在7 min内出峰,方法检出限（mg/L）、线性范围（mg/L）、相关系数分别为麻黄碱0.173、0.693-11.1、0.9993,可待因0.333、1.33-16.0、0.9993,应用于实际样品测定,回收率为94%-108%,RSD不大于3.5%。峰面积日内RSD不大于6.3%（n=5）,日间RSD不大于9.3%（n=5）。     

Determination of Tectorigenin in Rat Plasma: Application to a Pharmacokinetic Study After Oral Administration of Tectorigenin or Its Prodrug Tectoridin

A simple, sensitive, and validated liquid chromatographic method has been developed for the determination of tectorigenin in rat plasma and application to a pharmacokinetic study after oral administration of tectorigenin or its prodrug tectoridin. The analysis was performed on a Kromasil C₁₈ analytical column using gradient elution with acetonitrile 0.1% phosphonic acid water at 0.8 mL min^?1. The detection wavelength for UV detection was set at 264 nm. The established method was fully validated with parameters as follows: the intra- and inter-day assay precisions (CV) of three analytes were in the range of 4.2–13.3% and accuracies were between 98.0 and 107.5%; the calibration curve was linear with r ² > 0.99 over a concentration range of 0.02–2 μg mL^?1; the lower limit of quantification was 0.02 μg mL^?1; tectorigenin showed stable in rat plasma after 12 h incubation at room temperature, 15 days storage at ?80 °C and three freeze/thaw cycles, as well as in reconstitute buffer for 24 h at 25 °C; and the mean recoveries of tectorigenin were 92.3 ± 3.2, 95.5 ± 2.9 and 94.5 ± 3.0% with quality control levels of 0.02, 0.2 and 2 μg mL^?1, respectively. In conclusion, this method is simple, economic, and sensitive enough for in vivo pharmacokinetic studies of tectorigenin.     

肝糖选择剂-毛细管电泳手性拆分盐酸度洛西汀对映体及分离机制

以肝糖为毛细管电泳手性选择剂,对盐酸度洛西汀对映体的分离进行研究,建立了拆分方法.考察了手性选择剂浓度、运行缓冲液的离子强度、pH值及分离电压对手性分离的影响.在3.0% (m/V)肝糖、50 mmol/L Tris-H3PO4(pH 3.0)的运行缓冲液中,分离电压25 kV时,盐酸度洛西汀两对映体分离度达1.84.对分离机制进行了初步探讨.     

Rapid enantiomeric separation of polychlorinated biphenyls by electrokinetic chromatography using mixtures of neutral and charged cyclodextrin derivatives

Electrokinetic chromatography with cyclodextrin derivatives (CD-EKC) was used to achieve the rapid enantiomeric separation of chiral polychlorinated biphenyls (PCBs). Thirteen of the 19 chiral PCBs stable at room temperature were individually separated into their two enantiomers by using 2-morpholinoethanesulfonic acid (MES) buffer (pH 6.5) containing carboxymethylated gamma-cyclodextrin (CM-gamma-CD) as pseudostationary phase mixed with beta-cyclodextrin (beta-CD) or permethylated beta-cyclodextrin (PM-beta-CD). Urea was also added to increase the solubility of PCBs and cyclodextrins in the aqueous separation buffer. Several experimental parameters such as the nature, concentration, and pH of the buffer, nature and concentration of the cyclodextrin derivatives used, and the addition of different additives were studied in order to improve the enantiomeric separation. In addition, the effect of some instrumental parameters such as separation temperature and applied voltage was also investigated. PCBs were enantiomerically separated in less than 12 min by using a 50 mM MES buffer (pH 6.5) containing 20 mM CM-gamma-CD, 10 mM beta-CD or 20 mM PM-beta-CD, and 2 M urea at a temperature of 45 degrees C and an applied voltage of 20 kV.     

咖啡因及其9种类似物的胶束电动毛细管分析研究

 以十二烷基硫酸钠 (SDS)胶束为准固定相 ,考察了咖啡因及其 9种类似物在胶束电动毛细管 (MECC)分离模式下的分离行为。研究了运行缓冲液的 pH值、磷酸盐浓度、SDS浓度、甲醇体积分数、分离电压、分离温度等因素对这 10种化合物的迁移时间和分离效果的影响。结果发现 ,这些因素对上述 10种化合物的分离有显著的影响 ,尤以pH值为最。它不仅影响化合物的迁移时间和分离效率 ,还改变其出峰顺序 ,这与碱性条件下化合物仲胺基上氢的电离有关。优化后的分离条件 :运行缓冲液为 2 0mmol/L磷酸盐 2 0mmol/LSDS(pH 11 0 ) ,分离电压为2 5kV。     

Determination of Tectorigenin in Rat Plasma: Application to a Pharmacokinetic Study After Oral Administration of Tectorigenin or Its Prodrug Tectoridin

A simple, sensitive, and validated liquid chromatographic method has been developed for the determination of tectorigenin in rat plasma and application to a pharmacokinetic study after oral administration of tectorigenin or its prodrug tectoridin. The analysis was performed on a Kromasil C₁₈ analytical column using gradient elution with acetonitrile 0.1% phosphonic acid water at 0.8 mL min⁻¹. The detection wavelength for UV detection was set at 264 nm. The established method was fully validated with parameters as follows: the intra- and inter-day assay precisions (CV) of three analytes were in the range of 4.2–13.3% and accuracies were between 98.0 and 107.5%; the calibration curve was linear with r ² > 0.99 over a concentration range of 0.02–2 μg mL⁻¹; the lower limit of quantification was 0.02 μg mL⁻¹; tectorigenin showed stable in rat plasma after 12 h incubation at room temperature, 15 days storage at −80 °C and three freeze/thaw cycles, as well as in reconstitute buffer for 24 h at 25 °C; and the mean recoveries of tectorigenin were 92.3 ± 3.2, 95.5 ± 2.9 and 94.5 ± 3.0% with quality control levels of 0.02, 0.2 and 2 μg mL⁻¹, respectively. In conclusion, this method is simple, economic, and sensitive enough for in vivo pharmacokinetic studies of tectorigenin.

     

Capillary zone electrophoresis for the determination of thiabendazole, prochloraz and procymidone in grapes

Capillary zone electrophoresis with UV detection was applied to the simultaneous determination of thiabendazole, prochloraz and procymidone in grapes. Electrolyte conditions such as pH, composition and concentration of the buffer, addition of organic solvent and working voltage were checked to obtain a high-performance separation of the three fungicides (by measurement of separation efficiency and resolution). The most critical parameter was the pH of the running buffer. The best separation was achieved in 4 mM phosphate solution at pH 3.5. The repeatability of the migration times, expressed as RSD, was < 0.44%. The three peaks were completely resolved with a separation efficiency up to 100,000 theoretical plates. Solid-phase extraction was used for the isolation and preconcentration of the fungicides, which provided a concentration factor of 10:1 and limits of detection lower than the maximum residue limits. The mean recoveries of the fungicides were 73.75% for thiabendazole, 41.70% for prochloraz and 92.23% for procymidone. This method was used to determine these compounds in 20 real samples taken from a local market.     

Enantioseparation of palonosetron hydrochloride by micellar electrokinetic chromatography with sodium cholate as chiral selector

The enantioseparation of four stereoisomers of palonosetron hydrochloride by micellar electrokinetic chromatography using sodium cholate as chiral surfactant was described. Sodium cholate was shown to be effective in separating palonosetron hydrochloride stereoisomers. For method optimization, several parameters such as sodium cholate concentration, buffer pH and concentration, the types and concentration of organic modifiers and applied voltage, on the enantioseparation were evaluated and the optimum conditions were obtained as follows: 30 mM borate buffer (pH 9.40) containing 70 mM sodium cholate and 20% (v/v) methanol with an applied voltage of 20 kV. Under these conditions, baseline separation of palonosetron hydrochloride stereoisomers was achieved within 18 min.     

Determination of rhein and physcion in rhubarb by microchip capillary electrophoresis in mixed hydro-organic solvent combined with laser-induced fluorescence detection

Microchip capillary electrophoresis in mixed hydro-organic solvent combined with laser-induced fluorescence detection was developed for the separation and detection of physcion and rhein in rhubarb. In contrast to the conventional capillary electrophoresis method, ammonium acetate-dimethyl sulfoxide was used as the basic buffer system in this method. The effects of background buffer, buffer apparent pH*, buffer concentration, water ratio, sample preparation method, and separation voltage on separation and detection were investigated. Optimized separation and detection conditions were obtained: the buffer consisted of 20 mmol/L of ammonium acetate in hydro-organic solvent composed dimethyl sulfoxide, formamide, and water mixed at 60/20/20 (v/v/v) ratio. The separation voltage was 1.9 kV. Under these conditions, the physcion, rhein, and other components of rhubarb can be completely separated within 150 s. Under the methodological verification, good linearity (R ≥ 0.9995) for physcion and rhein, and low limits of detection (0.085 μg·mL⁻¹ and 0.077 μg·mL⁻¹, respectively), satisfactory peak area precisions, migration time precisions (1.74%–3.09%), and accuracy (recovery rate 97.8% and 101.4%) were achieved. It is shown that the proposed method is simple, efficient, fast, sensitive, simple instrument, consumes few samples, has low operating cost, and is linear.     

肌肽类生物活性肽的毛细管电泳在线富集技术

建立了毛细管区带电泳(CZE)在线富集3种肌肽类活性肽(肌肽、鹅肌肽和高肌肽)的两种简便有效的方法。一种是大体积进样反向压力排除基体富集（LVSRP）技术,即通过流体动力学进样,在不改变电源极性的条件下,利用反向压力排除样品基体,电堆积富集后进行CZE分离;另一种是大体积进样电渗流排除基体富集（LVSEP）技术,即通过流体动力学进样,于运行缓冲液中加入溴化十六烷基三甲基铵(CTAB)动态修饰毛细管表面,通过电渗流排除样品基体,改变电源极性后进行CZE分离。与常规CZE相比,LVSRP技术和LVSEP技术使检测灵敏度提高了40~60倍。对影响两种富集过程的一些因素进行了研究,在最优富集条件下考察本方法的线性范围为0.080~5.0 μmol/L。对3种生物活性肽的检测限(S/N=3)分别为LVSRP 41~58 nmol/L,LVSEP 35~43 nmol/L。