微乳毛细管电动色谱快速分析脂溶性维生素

建立了一种新的微乳体系,成功地应用于微乳毛细管电动色谱(MEEKC)快速分析脂溶性维生素VA、VD3和VE.本微乳液的组成为:1.2%(m/m)十二烷基硫酸钠(SDS)-21%(V/V)正丁醇-18%(V/V )乙腈-0.8%(m/m)正己烷-20 mmol/L H3BO3-Na2B4O7缓冲液( pH 8.4 ).该微乳体系中,助表面活性剂正丁醇和有机溶剂乙腈对脂溶性维生素的分离起到了重要的作用.当分离电压为25 kV,柱温为25 ℃时,VA、VD3和VE在13 min内达到基线分离.3种脂溶性维生素的迁移时间和峰面积的RSD(n= 5)<2.5%和4.5%;VA、VD3和VE分别在20～1000、5～1000和5～1000 mg/L范围内与峰面积呈线性关系;检出限(S/N=3)分别为12、 0.72和0.29 mg/L.本体系应用于市售VE胶囊的测定,结果与标示值相符.     

亲和超滤耦联液相色谱-质谱快速检测山楂叶中的α-淀粉酶抑制剂

建立了用于快速检测山楂叶中α-淀粉酶抑制剂的生物亲和超滤方法。考察了磷酸盐缓冲液的pH值、离子强度、孵育时间、孵育温度、α-淀粉酶浓度等影响亲和超滤的因素,最终选择了10 mmol/L磷酸盐缓冲液(pH 7.4)作为孵育溶液,在37℃孵育45 min,淀粉酶浓度为10 g/L。在优化条件下,将本法应用于山楂叶总黄酮的α-淀粉酶抑制剂的筛选,得到3个活性成分,分别鉴定为槲皮素-3-o-鼠李糖基-(1→4)-葡萄糖基-(1→4)-鼠李糖苷、牡荆素-2″-葡萄糖苷、牡荆素-2″-鼠李糖苷。这3个化合物的α-淀粉酶抑制活性为首次报道。     

鼠李糖脂应用于微乳毛细管电动色谱快速测定化妆品中激素类物质

采用生物表面活性剂鼠李糖脂建立了无需助表面活性剂的微乳体系,并应用于微乳毛细管电动色谱快速分析化妆品中皮质类激素泼尼松、泼尼松龙和氢化可的松。考察了pH值、鼠李糖脂浓度、离子强度、油相种类和浓度、分离温度、分离电压及进样电压和时间的影响,得出微乳体系最佳组成为0.1%(w/w)鼠李糖脂+0.8%(w/w)正庚烷+99.1%(w/w)硼砂缓冲液(80 mmol/L,pH 9.2)。分离温度20℃,分离电压20kV,电动进样10 kV×3 s,泼尼松、氢化可的松和泼尼松龙在9.4 min内可基线分离。重复进样7次,迁移时间和峰面积的RSD分别小于0.2%和5.0%。3种分析物线性范围均为5～100 mg/L;检出限分别为1.0,1.1和1.3 mg/L(S/N=3)。仅需简单萃取即可用于化妆品样品测定,回收率为81.6%～108%;RSD均小于4.8%。     

高效液相色谱-串联质谱法同时测定银杏保健茶中的16种黄酮类功效成分

建立了银杏保健茶中16种黄酮类物质的液相色谱-串联质谱(LC-MS/MS)测定方法。16种黄酮成分分别为儿茶素、牡荆素、葛根素、大豆苷元、水飞蓟宾、槲皮素、木犀草素、芹菜素、柚皮素、橙皮素二氢查尔酮、山柰酚、橙皮素、异鼠李素、黄芩素、川陈皮素、桔皮素。实验优化了液相色谱条件和质谱参数。采用C₁₈柱分离,流动相为乙腈-水(含0.1%甲酸)梯度洗脱,流速0.25 mL/min,以电喷雾离子源正离子多反应监测(MRM)模式进行MS/MS检测。16种黄酮类物质在各自的线性范围内具有良好的线性关系,相关系数大于0.996,低、中、高3个添加水平的平均回收率在70.9%~100.0%之间,相对标准偏差小于10%。通过检测发现实际样品中9种黄酮物质含量较高,分别是:山柰酚、槲皮素、橙皮素、牡荆素、木犀草素、儿茶素、芹菜素、柚皮素、异鼠李素,占总量的99.6%,此9种物质可作为银杏保健茶的质量控制指标。本法简便、快速、准确可靠,可用于控制银杏保健茶的质量。     

微乳液相色谱法同时测定降压中成药及保健品中添加的10种化学药物

建立了微乳液相色谱(MELC)同时测定中成药及保健品中添加的10种降压药物的分析方法。考察了微乳流动相的组成成分(包括表面活性剂、助表面活性剂、油相的种类及质量分数)、pH值和固定相种类对分离效果的影响。同时利用星点设计-响应面优化法进一步优化微乳组成。实验得到的最佳分离条件:色谱柱为Agela Promosil C18(2)(250 mm×4.6 mm,5μm);微乳流动相为5.6%(质量分数)十二烷基聚乙二醇醚(Brij35)-0.17%(质量分数)十二烷基硫酸钠(SDS)-5.1%(质量分数)正丁醇-0.46%(质量分数)环己烷-水(pH 3.0);流速为1.0mL/min;检测波长为230 nm;柱温为30℃。该方法具有灵敏度高、稳定性好和环保的优点。     

甲基丙烯酸酯整体柱毛细管电色谱法快速分析白芷中的主要活性成分

以甲基丙烯酸酯整体柱为分离柱,建立了一种快速分离、分析白芷药材提取物中的主要活性成分欧前胡素(imperatorin)、异欧前胡素(isoimperatorin)、珊瑚菜内酯(phelloptorin)和发卡二醇(falcarindiol)的毛细管电色谱(CEC)方法。在整体柱制备实验中对三元致孔剂组成成分的比例进行了系统的考察。在分离实验中对流动相的组成(包括有机相组成、缓冲液浓度和缓冲液的pH值)进行了优化。最终的优化条件为: 流动相为乙腈-20 mmol/L NaH2PO4(pH 4.95)(50:50, v/v),分离电压为－25 kV。结果表明,所制备的甲基丙烯酸酯毛细管整体柱具有良好的渗透性和重现性;4种分析物的标准曲线线性关系良好(r2＞0.997),检出限均小于0.34 mg/L,加样回收率为95.18%～98.44%。该方法快速、简便、可靠。应用该方法对18个不同产地的白芷样品进行了测定,并对其药材质量进行了评价。     

高效液相色谱法同时测定广陈皮药材中的11种化学成分

采用高效液相色谱法(HPLC)同时测定了广陈皮药材中5-羟甲基糠醛、维采宁-2、橙皮苷、橙皮素、异甜橙黄酮、甜橙黄酮、异黄芩配基甲醚、川陈皮素、3,5,6,7,8,3',4'-七甲氧基黄酮、橘皮素及5-去甲川陈皮素11种化学成分的含量。样品经50%(v/v)甲醇于70 ℃回流提取。在优化的色谱条件(Hanbon Benatach C18色谱柱(250 mm×4.6 mm, 5 μm)为分离柱,乙腈和0.2%甲酸水溶液为流动相,梯度洗脱,流速1.0 mL/min,柱温25 ℃,检测波长280 nm)下,提取液中的各成分分离良好,在选定的浓度范围内呈良好的线性关系(r>0.998),定量限(S/N=10)为0.0502~4.99 mg/L,检出限(S/N=3)为0.0125~1.25 mg/L,平均加标回收率(n=3)为96.4%~102.4%,相对标准偏差为0.25%~4.01%。该方法准确性高、重复性好,可用于广陈皮的质量控制。     

毛细管电泳柱后衍生激光诱导荧光测定动物组织中卡那霉素类抗生素

采用毛细管电泳柱后衍生激光诱导荧光测定3种卡那霉素类抗生素。研究了在反向电渗流条件下HAc-NaAc缓冲液酸度和浓度对卡那霉素类抗生素分离的影响,研究了Na2B4O7缓冲体系和柱后衍生试剂萘二醛/2-巯基乙醇浓度对检测信号的影响。采用50 mmol/L HAc-NaAc(pH5.0) 0.5 mmol/L CTMAB溶液为分离缓冲液,样品在-15 kV下分离,与柱后衍生试剂1.0 mmol/L NDA 8.0 mmol/L 2-ME 35 mmol/LNa2B4O7(pH10.0)的30%(V/V)甲醇溶液反应,激发诱导荧光检测卡那霉素类抗生素检出限为3.6×10-5~5.2×10-5g/L;本方法用于动物组织中卡那霉素类抗生素残留检测,相对标准偏差小于7.2%;回收率为90.2%~95.3%(n=4)。     

高速逆流色谱分离与鉴定鹿药中黄酮类化合物

采用高速逆流色谱(HSCCC)与其它色谱联用的方法分离纯化鹿药中的化学成分,得到5个黄酮类化合物: 5,7,3′,4′-四羟基-3-甲氧基-8-甲基黄酮(1)、 8-甲基木犀草素(2)、 3′-甲氧基木犀草素(3)、 木犀草素(4)和槲皮素(5),它们均为首次自该种及该属植物中分离得到.HSCCC以V(氯仿)∶ V(甲醇)∶ V(水)=4∶ 3∶ 2混合液为溶剂,上相为固定相,下相为流动相, 分离纯化得到3个分别含化合物1, 4和5的主要部分,经HPLC检验纯度分别为98.3%, 96.7%和95.3%;还有1个含有化合物2和3的较纯部分,通过Sephadex LH-20柱色谱,以V(甲醇)∶ V(水)=1∶ 1混合液洗脱将二者分离.通过理化性质及紫外、红外、质谱、核磁等波谱分析确定化合物结构.     

柱前衍生反相高效液相色谱分离和测定氨基酸--用N-羟基琥珀酰亚胺-α-萘乙酸酯作衍生试剂

以N-羟基琥珀酰亚胺-α-萘乙酸酯(SINA)为氨基酸的柱前衍生试剂,反相高效液相色谱分离测定了15种氨基酸.采用含10 mmol/L pH 5.0的乙酸-乙酸钠缓冲溶液的甲醇-乙酸乙酯-水(10/2/88,V/V/V)溶液为流动相体系,分离测定了7种氨基酸;用甲醇-乙酸乙酯-水(26/2/77,V/V/V)分离测定了5种氨基酸;用甲醇-乙酸乙酯-水(45/2/53,V/V/V)分离测定了3种氨基酸.检测限均达到pmol级,且重现性好.     

Simultaneous determination of vitexin-2"-O-glucoside, vitexin-2"-O-rhamnoside, rutin, and hyperoside in the extract of hawthorn (Crataegus pinnatifida Bge.) leaves by RP-HPLC with ultraviolet photodiode array detection

RP-HPLC with UV photodiode array detection (UV-DAD) was developed and validated for the simultaneous determination of vitexin-2"-O-glucoside, vitexin-2"-O-rhamnoside, rutin, and hyperoside in the extract of hawthorn (Crataegus pinnatifida Bge.) leaves. The analytes of interest were separated on a Diamonsil C18 column (250 x 4.6 mm id, 5 microm) with the mobile phase consisting of THF/ACN/methanol/ 0.05% phosphoric acid solution (pH 5.0) (18:1:1:80 v/vl/v). The flow rate was set at 1.0 mL/min and the eluent was detected at 340 nm for the four flavonoids. The method was linear over the studied range of 1.00-100 microg/mL for the four analytes of interest with the correlation coefficient for each analyte greater than 0.999. The LOD and LOQwere 0.03 and 0.10 microg/mL, 0.03 and 0.10 microg/mL, 0.05 and 0.15 pg/mL, 0.10 and 0.30 microg/mL for vitexin-2"-O-glucoside, vitexin-2"-0-rhamnoside, rutin, and hyperoside, respectively. The optimized method was successfully applied to the analysis of four important flavonoids in the extract of hawthorn leaves. The total amounts of the four flavonoids were 22.2, 62.3, 4.27, and 8.24 mg/g dry weight for vitexin-2"-O-glucoside, vitexin-2"-O-rhamnoside, rutin, and hyperoside in the extract of hawthorn leaves, respectively.     

微乳液相色谱法同时测定4种脂溶性维生素

建立了一种新的微乳体系,并成功地应用于微乳液相色谱法(MELC)快速分析脂溶性维生素VA、VD2、VD3和VE。通过对影响分离选择性的主要因素进行考察,得到最佳微乳体系组成为98%(v/v)(50 g/L十二烷基硫酸钠(SDS)-10%(质量分数)正丁醇-1.0%(质量分数)正辛烷-84%水(质量分数))-2%(v/v)乙腈。该微乳体系中,表面活性剂类型和浓度、油相正辛烷的含量、有机添加剂乙腈对脂溶性维生素的分离起到了重要的作用。以Venusil ASB C18色谱柱(150 mm×4.6 mm, 5 μm)为分离柱,流速为0.7 mL/min,检测波长为265 nm,柱温为40 ℃, VA、VD2、VD3和VE在20 min内达到基线分离。4种脂溶性维生素的保留时间和峰面积的相对标准偏差(RSD) (n=5)分别小于2.3%和3.0%; VA、VD2、VD3和VE的线性范围分别为22.0～88.0 mg/L、20.2～81.0 mg/L、24.3～97.2 mg/L和125.0～500.0 mg/L,相应的线性相关系数r2分别为0.9996、0.9994、0.9998、0.9998;检出限(S/N=3)分别为0.37、0.34、0.41和2.12 mg/L。本方法已成功应用于多维元素片(21)中VA与VE的测定,结果令人满意。     

Validation of an oil-in-water microemulsion liquid chromatography method for analysis of perindopril tert-butylamine and its impurities

This paper describes the development and validation of a microemulsion liquid chromatography (MELC) method for simultaneous determination of perindopril tert-butylamine and its impurities in bulk active substances and the pharmaceutical dosage form of tablets. An appropriate resolution with reasonable retention times was obtained for a microemulsion containing 0.24% (w/v) butyl acetate, 0.30% (w/v) ethyl acetate, 2% (w/v) sodium dodecyl sulfate, 7.75% (w/v) n-butanol, and 20.0 mM potassium dihydrogen phosphate, the pH of which was adjusted to 3.70 with 85% orthophosphoric acid. Separations were performed on a Nucleosil 120-5 butyl modified (C4), 250 x 4 mm, 5 microm particle size silica column at 40 degrees C, with a mobile phase flow rate of 1.25 mL/min. UV detection was performed at 254 nm. The established method was subjected to method validation, and required validation parameters were defined. Robustness testing, an important part of method validation, was performed as well. Since robustness validation can be conducted using different experimental designs, the Plackett-Burman design was applied due to its possibility of testing many factors at the same time. The validated MELC method was found to be suitable for the simultaneous determination of perindopril tert-butylamine and its impurities in pharmaceuticals.     

水包油型微乳液相色谱分离激素类药物的影响因素

采用水包油型微乳液相色谱(MELC)分离了6种激素类药物(醋酸可的松、泼尼松龙、己烯雌酚、炔雌醇、醋酸氟轻松及黄体酮)。考察了微乳流动相的组成成分(包括表面活性剂的浓度、油相种类、有机添加剂种类)及固定相孔径等对分离的影响。实验得到的最佳分离条件: 色谱柱为Venusil ASB C18 (T)(粒径5 μm,孔径30 nm,250 mm×4.6 mm),微乳流动相为30 g/L十二烷基硫酸钠(SDS)-0.8%正辛烷-6.6%正丁醇,流速为0.8 mL/min,检测波长为254 nm,柱温为35 ℃。该方法可用于甾体药物及其制剂的分离鉴别以及快速测定。     

Comparison of HPLC and MEEKC for Miconazole Nitrate Determination in Pharmaceutical Formulation

A simple solid phase extraction (SPE) method coupled with high performance liquid chromatography (HPLC) using UV detector and microemulsion electrokinetic chromatography (MEEKC) has been developed and compared for the quantitative determination of miconazole nitrate in pharmaceutical formulation. For HPLC method, two parameters were optimized, namely, the wavelength and the mobile phases. The optimized condition was at the 225 nm wavelength and the mobile phase of ACN:MeOH (90:10 v/v). There are seven MEEKC parameters that were optimized, in this research, which were applied to voltage, temperature, wavelength, sodium dodecyl sulfate (SDS) concentration, buffer pH, buffer concentration and butan-1-ol concentration. The optimum MEEKC condition was obtained using 86.35 % (w/w) 2.5 mM borate buffer pH 9, 0.25 % (w/w) SDS, 0.8 % (w/w) ethyl acetate, 6.6 % w/w butan-1-ol and 6.0 % (w/w) acetonitrile. The combination of SPE using a diol column with HPLC–UV and the MEEKC methods were successfully applied for the determination of miconazole nitrate in a pharmaceutical formulation with the recovery percentage of 98.35 and 92.50 %, respectively.     

Comparison of HPLC and MEEKC for Miconazole Nitrate Determination in Pharmaceutical Formulation

A simple solid phase extraction (SPE) method coupled with high performance liquid chromatography (HPLC) using UV detector and microemulsion electrokinetic chromatography (MEEKC) has been developed and compared for the quantitative determination of miconazole nitrate in pharmaceutical formulation. For HPLC method, two parameters were optimized, namely, the wavelength and the mobile phases. The optimized condition was at the 225 nm wavelength and the mobile phase of ACN:MeOH (90:10 v/v). There are seven MEEKC parameters that were optimized, in this research, which were applied to voltage, temperature, wavelength, sodium dodecyl sulfate (SDS) concentration, buffer pH, buffer concentration and butan-1-ol concentration. The optimum MEEKC condition was obtained using 86.35 % (w/w) 2.5 mM borate buffer pH 9, 0.25 % (w/w) SDS, 0.8 % (w/w) ethyl acetate, 6.6 % w/w butan-1-ol and 6.0 % (w/w) acetonitrile. The combination of SPE using a diol column with HPLC–UV and the MEEKC methods were successfully applied for the determination of miconazole nitrate in a pharmaceutical formulation with the recovery percentage of 98.35 and 92.50 %, respectively.

     

Sample stacking and sweeping in microemulsion electrokinetic chromatography under pH-suppressed electroosmotic flow

Two on-line sample concentration techniques, sample stacking and sweeping under pH-suppressed electroosmotic flow, were evaluated in microemulsion electrokinetic chromatography. The concept of stacking with anion selective electrokinetic injection and a water plug in a reverse-migrating microemulsion (SASIW-RMME) was brought forward in this article. Six flavonoids were concentrated using a microemulsion consisting of 80 mM sodium dodecyl sulfate, 1.2% (v/v) ethyl acetate, 0.6% (v/v) 1-butanol, 10% acetonitrile (v/v) and 50 mM phosphoric acid (pH* 1.8). Significant detector response improvements were achieved. The limits of detection were in the low ng/ml level. Finally, the sample of Fructus aurantii Immaturus was analyzed using sweeping technique.     

Determination of the lipophilicity of Salvia miltiorrhiza Radix et Rhizoma (danshen root) ingredients by microemulsion liquid chromatography: optimization using cluster analysis and a linear solvation energy relationship‐based method

We evaluated 26 microemulsion liquid chromatography (MELC) systems for their potential as high‐throughput screening platforms capable of modeling the partitioning behaviors of drug compounds in an n‐octanol–water system, and for predicting the lipophilicity of those compounds (i.e. logP values). The MELC systems were compared by cluster analysis and a linear solvation energy relationship (LSER)‐based method, and the optimal system was identified by comparing their Euclidean distances with the LSER coefficients. The most effective MELC system had a mobile phase consisting of 6.0% (w/w) Brij35 (a detergent), 6.6% (w/w) butanol, 0.8% (w/w) cyclohexane, 86.6% (w/w) buffer solution and 8 mm cetyltrimethyl ammonium bromide. The reliability of the established platform was confirmed by the agreement between the experimental data and the predicted values. The logP values of the ingredients of danshen root (Salvia miltiorrhiza Radix et Rhizoma) were then predicted. Copyright © 2015 John Wiley & Sons, Ltd.     

Phase-transfer catalytic determination of phenols as methylated derivatives by gas chromatography with flame ionization and mass-selective detection

A microemulsion electrokinetic chromatographic (MEEKC) method was developed for the separation of six catechins, specific marker phytochemicals of Cistus species. The MEEKC method involved the use of sodium dodecyl sulfate (SDS) as surfactant, heptane as organic solvent and butan-1-ol as co-solvent. In order to have a better stability of the studied catechins, the separation was performed under acidic conditions (pH 2.5 phosphate buffer). The effects of SDS concentration and of the amount of organic solvent and co-solvent on the analyte resolution were evaluated. The optimized conditions (heptane 1.36% (w/v), SDS 2.31% (w/v), butan-1-ol 9.72% (w/v) and 50 mM sodium phosphate buffer (pH 2.5) 86.61% (w/v)) allowed a useful and reproducible separation of the studied analytes to be achieved. These conditions provided a different separation profile compared to that obtained under conventional micellar electrokinetic chromatography (MECK) using SDS. The method was validated and applied to the determination of catechin and gallocatechin in lyophilized extracts of Cistus incanus and Cistus monspeliensis.