托吡卡胺对映体的毛细管电泳-方波安培分离检测

采用毛细管电泳-方波安培检测法,在熔融石英毛细管(75 μm i.d.×50 cm)中,以7 mmol/L 三羟甲基氨基甲烷(Tris)-10 mmol/L柠檬酸-2 mmol/L硼酸-15mmol/L β-环糊精 （β-CD） (pH 3.0)为电泳介质,采用重力进样,高度差为20 cm,进样时间为10 s,在分离电压为15 kV,方波平衡电位+0.8 V的条件下,实现了托吡卡胺对映体的分离检测。线性范围为5~750 μmol/L,检出限为2 μmol/L。对影响分离度的因素β-CD浓度、硼酸浓度及p     

场放大进样-胶束扫集毛细管电脉法测定痕量泼尼松

建立了胶束毛细管电动色谱在线富集技术测定药品中痕量的泼尼松的方法。在胶束扫集的基础上联用场放大进样,使泼尼松的富集倍数提高了136倍;检出限由原来的2.7mg/L降至20μg/L。胶束扫集毛细管电泳缓冲体系为120mmol/LSDS、10mmol/LNaH2PO4(pH2.5)10%乙腈(V/V)。分离电压-20kV,进样电压-20kV,进样时间70s,进水时间180s,检测波长250nm。同时讨论了SDS浓度、样品基质pH、进样电压、进水时间和进样时间对分离效果的影响。实验结果显示:在优化实验条件下,样品的检测仅需8min,泼尼松在0.05～10mg/L的范围内线性关系良好(r=0.998)。回收率在89.4%～106%之间,相对标准偏差在2.1%～2.6%之间,可用于各种中药制剂中泼尼松的含量测定。     

在线扫集-胶束毛细管电动色谱法测定扛板归中的阿魏酸、咖啡酸和原儿茶酸

采用在线扫集-胶束毛细管电动色谱法(sweeping-MEKC)分离测定扛板归中的阿魏酸、咖啡酸和原儿茶酸。采用未涂层熔融石英毛细管(50 cm×50μm,有效柱长36 cm);环境温度25℃;缓冲体系为20 mmol/L NaH2PO4-80mmol/L十二烷基磺酸钠(SDS)-12.5%乙腈(V/V)(pH 2.20),紫外检测波长为216 nm,运行分离电压-20 kV,进样时间100 s。在优化条件下,3种有机酸均在20 min内出峰,峰面积RSD均小于5%。检出限分别达到98.52,118.73和27.27μg/L。     

毛细管电泳中移动反应界面法富集和检测尿样中的氧化苦参碱

采用建立在移动反应界面理论上的体系进行尿样中氧化苦参碱的富集与定量检测。与传统的毛细管电泳相比,体系中引入了富集缓冲溶液(富集相)和分离缓冲溶液(分离相)。优化的条件如下:样品缓冲溶液为20 mmol/L 甲酸钠(用氨水调节pH至10.70),富集缓冲溶液为40 mmol/L 甲酸-甲酸钠(pH 2.60),分离缓冲溶液为100 mmol/L 甲酸-甲酸钠(pH 4.80);样品相压力进样1.4 kPa×3 min,富集相压力进样1.4 kPa×7 min,紫外检测波长210 nm,电压21 kV。氧化苦参碱在2.2~65 mg/L的质量浓度范围内呈良好的线性关系(r=0.9991),检出限为0.74 mg/L,灵敏度比常规毛细管电泳方法提高约70倍,重现性良好。该方法已经成功地应用于尿样中氧化苦参碱的检测。     

阳离子选择性耗尽进样-胶束扫集法测定尿液中的麻黄碱和可待因

联用选择性耗尽进样和胶束扫集两种在线富集技术,建立了尿样中麻黄碱和可待因含量测定的灵敏方法,并通过日内、日间、柱间实验考察了方法的稳定性.胶束扫集电动色谱缓冲体系为80 mmol/L 十二烷基磺酸钠(SDS)-20 mmol/L NaH2PO4(pH 2.20)-18%乙腈(V/V),分离电压-20 kV,进样电压10 kV,进样时间150 s,测量波长200 nm.同时讨论了pH值、SDS浓度、选择性耗尽进样萃取液电导、进样电压、进样时间和进水长度等对分离效果的影响.结果显示,方法富集功能很强,对麻黄碱和可待因含的富集倍数分别达5800和2490以上.在优化条件下,方法线性关系良好(r=0.9999),麻黄碱和可待因的线性范围分别为0.500～16.0 μg/L和2.00～48.0 μg/L,检出限分别为0.10和0.80 μg/L.方法稳定性良好,日内、日间和柱间的RSD分别为2.6%,5.9%和6.6%.应用于实际尿样分析,回收率在96.8%～106%之间,RSD≤4.7%,结果比较满意.     

扑尔敏对映体的毛细管电泳-方波安培分离检测

报道了以未涂层融硅石英毛细管(50 cm×75 μm)为分离柱,5 mmol/L NaOH+10 mmol/L Citric acid +3 mmol/L H3BO3+10 mmol/L β-CD (pH 3.5) 为电泳介质,分离电压12 kV,检测电压0.80 V,建立了朴尔敏对映体拆分的高效毛细管电泳-方波安培检测方法.对缓冲溶液的种类、浓度、pH、分离电压对拆分效果的影响进行了讨论,并对拆分机理进行了探讨.     

基于非接触电导检测和在线富集技术快速灵敏检测土壤中速效磷

针对土壤中速效磷的快速检测需求,建立了基于非接触电导检测和场放大进样在线富集技术的毛细管电泳分离检测土壤中水溶性磷酸盐的分析方法。对影响分离检测效果的实验条件（电泳运行液组成、pH值、分离电压、进样电压和时间）进行了考察和优化。采用毛细管区带电泳模式,以35 mmol/L乙酸 - 2 mmol/L乙酸铵溶液为电泳运行液,负高压分离（－14 kV）和场放大进样（－11 kV × 10 s）,磷酸根离子在8 min内可获良好分离和灵敏检测,检出限为5 μg/L,线性范围为16～800 μg/L。研究表明放大进样在线富集技术使检测灵敏度得到显著提高,富集因子可达580倍。日内和日间相对标准偏差（RSD）小于5.0%。土壤中共存的常见无机阴离子（Cl－、SO2?442-、NO?33-）、有机基质和浸出液基体颜色不干扰速效磷的测定,表现出较强的抗干扰能力。该方法无需复杂的前处理即可直接进样分析,具有简单快速、灵敏高效、分析成本低的优点。对实际土壤样品和国标土壤样品中的速效磷进行检测,检测结果与标准方法一致。     

毛细管电泳-安培检测法分离分析手性药物索他洛尔

采用毛细管电泳-柱端喷壁式安培检测技术,建立了痕量手性药物索他洛尔的分离检测新方法。以1.5%(w/V)羧甲基-β-环糊精为手性选择试剂,借助于环糊精-客体包合物的拆分原理,索他洛尔对映异构体在优化的分离条件:50mmol/LTris-H3PO4缓冲液(pH5.5),分离电压21kV,进样条件18kV/10s,工作电位1150mV(vs.Ag/AgCl),可实现基线分离,线性范围为5～500μg/L;异构体Ⅰ和Ⅱ的检出限(S/N=3)分别为2.0和1.9μg/L。本方法用于模拟血清样品分析,结果令人满意。     

毛细管电泳-柱端安培检测测定莲子心中荷叶碱、芦丁和金丝桃甙的含量

采用毛细管电泳-柱端安培检测测定莲子心中荷叶碱、芦丁和金丝桃甙的含量．研究了检测电位、运行缓冲液浓度和pH值,分离电压和进样时间对分离和检测的影响．以微碳圆盘电极（Ф=0.5ram）为工作电极,检测电位为＋0．95V（vs．Ag／AgCl）,pH为7．25的50mmol／L Na2B4O7和100mmol／L NaH2PO4缓冲液为运行液,当分离电压为15kV时,3种分析物在15min内完全分离．荷叶碱、芦丁和金丝桃甙的检出限（S／N=3）分别为0．02μg／mL、0．05μg／mL和0．04μg／mL．该方法已成功地应用于莲子心中上述3种活性成分的测定．     

毛细管电泳电致化学发光法测定家犬体内甲氧氯普胺的血药浓度

基于甲氧氯普胺对钌联吡啶电化学发光信号的增敏作用, 建立了检测甲氧氯普胺的毛细管电泳电致化学发光新方法. 最佳实验条件为: 检测电位1.18 V, 钌联吡啶浓度5 mmol/L, 检测池磷酸缓冲溶液40 mmol/L (pH 7.2), 分离磷酸缓冲溶液20 mmol/L (pH 6.1), 进样电压12 kV, 进样时间10 s, 分离电压14 kV. 方法的检测限(3σ)为5.0×10^－3 mg/L, 线性范围为 0.03～9.52 mg/L, 相关系数为0.9990, 回收率为98.0%～101.7%. 对家犬体内甲氧氯普胺血药浓度的监测发现, 给药1.5 h血药浓度达到最大值, 血药浓度的半衰期约为4 h. 本方法具有简便、快速、灵敏、进样量少等特点, 可用于甲氧氯普胺血药浓度监控和药物动力学研究.     

毛细管电泳高频电导法快速分离检测混合氨基酸

氨基酸(Am ino acids,AA s)是组成生物大分子的基本单元,与人的健康状况有极其密切的关系.在医学和生命科学研究中,微量氨基酸的分离检测具有重要意义.     

A new method of quantification of pipemidic-acid by capillary zone electrophoresis with end-column amperometric detection

Capillary zone electrophoresis was employed for the determination of pipemidic acid using an end-column amperometric detection with a carbon fiber microdisk array electrode, at a constant potential of -1.10 V vs. saturated calomel electrode. The optimum conditions of separation and detection were 1.2 x 10(-4) mol/LNaOAc - 8.8 x 10(-4) mol/ LHOAc for the buffer solution, 20 kV for the separation voltage, 5 kV and 10 s for the injection voltage and the injection time. The limit of detection was 1.05 x 10(-7) mol/L or 189 amol (S/N=3). The relative standard deviation was 0.31% for the migration time and 2.0% for the electrophoretic peak current. The method was applied to determining pipemidic acid in human serum.     

Analysis of amino acids by capillary zone electrophoresis with electrochemical detection

The precapillary derivatization of 20 amino acids with naphthalene-2,3-dicarboxaldehyde (NDA) and CN(-) was investigated. All these derivatized amino acids could be oxidized on the carbon fiber microdisk bundle electrode except proline. Capillary zone electrophoresis with electrochemical detection was employed for the analysis of 19 amino acids. The optimum conditions of separation and detection were borate, pH 9.48, for the electrolyte, 18 kV for the separation voltage and 1.15 V versus a saturated calomel electrode for the detection potential. Limits of detection of concentration or mass for individual amino acids were between 1.7 x 10(-7) and 1.8 x 10(-6) mol/L or 84 and 893 amol (according to the signal-to-noise ratio of 3) for the injection voltage of 6 kV and injection time of 10 s. The relative standard deviations were between 0.80 and 2.3% for the migration times and 1.4 and 6.4% for the electrophoretic peak currents. From a mixture of 19 amino acids, 10 amino acids (Arg, Lys, Orn, Try, Ser, Ala, Gly, Cys, Glu, Asp) could be well separated. The other 9 amino acids appeared on three electrophoretic peaks. From the samples, in which the nine amino acids do not exist simultaneously, some of them could also be detected. The method was applied to the determination of amino acids in beer by the standard addition method. The recovery for the amino acids in beer was 91-109%.     

Determination of clozapine by capillary zone electrophoresis following end-column amperometric detection with simplified capillary/electrode alignment

Capillary zone electrophoresis was employed for the determination of clozapine using an end-column amperometric detection at a carbon fiber array microdisk electrode with simplified capillary/electrode alignment. The optimum conditions of separation and detection are: Britton-Robinson buffer, pH 2.0 (1.3 x 10(-2) mol/L total concentration of acids, 3.2 x 10(-3) mol/L NaOH), 15 kV for separation voltage, 5 kV and 10 s for injection voltage and injection time, respectively. The limit of detection is 4.2 x 10(-7) mol/L or 1.2 fmole (signal to noise, S/N = 2). The relative standard deviation is 1.4% for the migration time and 2.5% for the electrophoretic peak current. The method was applied to the determination of clozapine in human blood. The recovery of the method is between 94-104%.     

采用隔离池的毛细管电泳-间接紫外吸收法测定茶叶中的氨基酸

改进的毛细管电泳-间接紫外吸收法采用了自制隔离池,以对氨基苯甲酸(PAB)为背景电解质,对茶叶中的氨基酸进行了测定。PAB能够提高分离效率,降低检出限。隔离池的使用避免了PAB的电极反应,降低了基线噪声,维持了两缓冲液池间的电流导通。研究了背景电解质的浓度、pH值以及电渗流改性剂的种类和浓度对氨基酸分离的影响。在优化的实验条件下,16种氨基酸在14 min内达到了基线分离,峰面积的相对标准偏差小于5%(n=5),检出限为1.7~4.5 μmol/L,回收率为83.0%~106%。该法快速、便捷和灵敏,已成功应用于茶叶中11种游离氨基酸的检测。     

Direct electrochemical determination of pyruvate in human sweat by capillary zone electrophoresis.

Capillary zone electrophoresis was employed for the determination of pyruvate in human sweat using electrochemical detection with a carbon fiber microdisk bundle electrode at a constant potential of 1.60 V vs. saturated calomel electrode. The optimum separation conditions are 3.6 x 10(-3) mol/L Na2HPO4-1.4 x 10(-3) mol/L NaH2PO4 (pH 7.2) for the buffer solution, and 18 kV for the separation voltage. The limits of detection of pyruvate are 8.0 x 10(-6) mol/L or 24 fmol (S/N = 3) for the injection voltage of 6 kV and the injection time of 10 s. The relative standard deviation is 2.0% for the migration time and 5.7% for the electrophoretic peak current. The method was applied to determining pyruvate in human sweat.     

毛细管电泳-间接紫外检测法测定蜂蜜中的氨基酸

采用毛细管电泳-间接紫外检测法同时分离测定蜂蜜中的赖氨酸、色氨酸、谷氨酸等9种氨基酸。考察了磷酸浓度、进样方式和缓冲液pH对分离效率和重现性的影响。在分离电压为-15 kV、检测波长为220 nm条件下,以含有0.5 mmol/L十六烷基三甲基溴化铵、20 mmol/L烟酸、10%甲醇的10 mmol/L磷酸二氢钠缓冲溶液(pH 10.2)为运行缓冲液,9种组分在11 min内达到基线分离;检出限最低可达到0.3 mg/L;线性范围为1.0~1000 mg/L;日间及日内精密度为0.64%~5.83%。实际样品中除甲硫氨酸外的8种氨基酸的加标回收率为60.00%~118.37%。将该方法应用于不同蜜源植物和产地的蜂蜜样品的测定,在市售的5种蜂蜜中均检测到脯氨酸、丝氨酸和天冬氨酸,而只在荔枝蜜中检测到苏氨酸。该方法可以为蜂蜜的蜜源鉴别及质量评估提供借鉴方法。     

Monitoring human serum transferrin by capillary zone electrophoresis with end-column amperometric detection

Capillary zone electrophoresis was employed for the determination of human serum transferrin using end-column amperometric detection with a carbon fiber microelectrode at a constant potential of 1.9 V vs. saturated calomel electrode (SCE). The optimum conditions of separation and detection are 7.5 x 10(-4) mol/L Tris-3.44 x 10(-4) mol/L HCl for the buffer solution, 20 kV for the separation voltage, 5 kV and 10 s for the injection voltage and the injection time, respectively. The limit of detection is 6.7 x 10(-8) mol/L or 440 amol (S/N = 2). The relative standard deviations are 0.67% for the migration time and 1.5% for the electrophoretic peak current. The method was applied to the determination of transferrin in human serum. The recovery is between 93-104%.     

Quantitative assay of metronidazole by capillary zone electrophoresis with amperometric detection at a gold microelectrode

Capillary zone electrophoresis was employed for the determination of metronidazole using end-column amperometric detection with a gold microelectrode at a constant potential of -0.52V vs. saturated calomel electrode. To overcome interference of oxygen in the solution, a deaeration injector and a deaeration protector at the detection cell were used. The optimum conditions of separation and detection are 1.0 x 10(-3) mol/L potassium dihydrogen citrate (KH2C6H5O7) for the buffer solution, 20 kV for the separation voltage, and 5 kV and 10 S for injection voltage and injection time, respectively. The limit of detection is 6.0 x 10(7) mol/L or 0.78 fmole (S/N = 3). The relative standard deviation is 3.9% for the electrophoretic peak current. The method was applied to the determination of metronidazole in human urine.