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）。     

胶束在线扫集毛细管电泳法测定三聚氰胺

研究胶束在线扫集毛细管电泳法测定三聚氰胺的可行性,结果表明,与区带毛细管电泳相比,胶束在线扫集毛细管电泳法富集倍数提高约60倍。缓冲体系为140 mmol/L SDS+20 mmol/L NaH2PO4(pH 2.20)+10%(体积分数)甲醇,分离电压-18 kV,进样时间30 s,测量波长214 nm。考察了SDS浓度、pH、进样时间、运行电压等因素对分离测定的影响情况。在优化条件下,三聚氰胺在9 min时出峰,峰面积RSD≤3.7%。方法检出限、线性范围、相关系数分别为:0.13μg/mL、0.50~32.0μg/mL、0.9997。方法可用于奶粉中三聚氰胺的分离测定。     

胶束扫集毛细管电泳分离测定绿原酸和咖啡酸

采用胶束扫集毛细管电泳分离测定双黄连口服液中的绿原酸和咖啡酸.试验条件为:重力进样时间40 s;以20 mmol/L NaH_2PO_4,100 mmol/L 十二烷基磺酸钠(SDS)为电泳缓冲液(含体积分数15%甲醇,pH 2.20),分离电压-20 kV,检测波长214 nm,讨论了pH、SDS浓度、样品溶剂等对分离效果的影响.在优化条件下,绿原酸和咖啡酸的检出限分别达到1.02和0.168 μg/mL,线性范围分别为5.86～51.5 μg/mL和1.27～14.5 μg/mL.     

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.     

胶束扫集毛细管电动色谱法测定药物中3种邻苯二甲酸酯

采用胶束扫集毛细管电动色谱技术,建立了测定药物中邻苯二甲酸二甲酯(DMP)、邻苯二甲酸二乙酯(DZP)和邻苯二甲酸二丁酯(DBP)的方法。电泳缓冲体系含80 mmol/L SDS,20 mmol/L NaH2PO4(pH 2.20),5%甲醇(V/V),分离电压-18 kV,重力进样80s×15.0cm,检测波长225 nm,使用Φ50μm×62.0 cm石英毛细管,有效长度50.0 cm。讨论了磷酸盐浓度、有机改善剂、SDS浓度、分离电压、进样时间等因素的影响,并考察了胶束扫集法对DMP、DEP和DBP的富集能力。在优化条件下,线性关系良好,相关系数大于0.9986,DMP、DEP和DBP的线性范围分别为1.25～240,1.04～200和1.56～200 mg/L,检出限分别为0.26,0.26和0.39 mg/L。方法应用于肠溶片中DMP、DEP和DBP的测定,回收率在93.3%～108%之间,RSD≤5.2%。每次样品测定可在10 min内完成。     

基于胶束反向扫集的毛细管电泳量子点电化学发光研究

研究了胺分子对CdSe量子点电化学发光的增强作用，构建了CdSe量子点电化学发光传感器.结合胶束扫集预富集技术，发展了一种基于胶束反向扫集的毛细管电泳（CE）量子点（QD）电化学发光（ECL）新方法用于莱克多巴胺和克伦特罗的同时分离检测.毛细管内首先充满含有十二烷基硫酸钠（SDS）胶束的缓冲溶液，电动进样时，样品分子进入毛细管，在入口端被迎面而来的SDS胶束捕获并富集，经CE分离后顺次进入检测端，根据不同浓度的胺分子对CdSe量子点发光强度的增强作用不同，实现对不同胺分子的同时分离检测.胶束反向扫集富集技术，使胶束-样品结合物在毛细管中处于准静止状态，进样时间可达50 min，量子点电化学发光信号增强6000倍.该方法成功用于猪肉样品中莱克多巴胺和克伦特罗的同时分离检测，其线性范围分别为（0.8~2960）和（3.0~5520）μg/L，检出限分别为96.8和192.5 ng/L.     

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。     

阴离子选择性耗尽进样-胶束扫集毛细管电泳法对痕量醋酸氢化可的松的测定

联用阴离子选择性耗尽进样和胶束扫集两种在线富集技术,建立了胶束毛细管电泳方法测定化妆品中醋酸氢化可的松的方法。讨论了SDS浓度、样品基体、进样电压、进水时间和进样时间对富集和分离的影响。优化的实验条件:以120 mmol/L SDS-20 mmol/L NaH2PO4(pH2.2)-10%(体积分数)甲醇为缓冲体系,分离电压-20 kV,进样电压-20 kV,进样时间80 s,进水时间200 s,测量波长250 nm。在该实验条件下,醋酸氢化可的松的富集倍数比普通毛细管电泳法提高了约173倍。方法的线性范围为0.05~5.0 mg/L,检出限为12.6μg/L。该方法用于化妆品中醋酸氢化可的松含量的测定,回收率为98%~105%,相对标准偏差均小于4.0%(n=4)。     

胶束毛细管电泳在线推扫富集技术测定血液中环丙沙星含量

采用在线Sweeping(推扫 )富集技术 ,建立了胶束毛细管电泳法测定血液中痕量乳酸环丙沙星的方法。考察了背景溶液pH值、SDS浓度、进样时间、血样预处理方法等对乳酸环丙沙星富集效果的影响。使用未涂层的毛细管柱 (5 5cm× 75 μmi.d .,有效柱长 4 7cm) ,30mmol/L硼砂 +80mmol/L十二烷基硫酸钠 (pH =9.4 0 )为背景溶液 ,在紫外检测波长 2 5 4nm、运行电压 1 8kV条件下 ,血浆样品用乙腈除蛋白后直接在线Sweep ing富集 ,富集倍数可达 6 0 0倍。线性范围在 0 .0 4～ 1 0mg/L (r =0 .999,n =8)。检出限为 0 .0 1mg/L。本方法减少了样品预处理的繁琐过程 ,弥补了毛细管电泳 (CE)在测定血液中痕量组分方面的不足 ,为CE在体内痕量药物分析等方面的应用提供了新的方法     

胶束扫集-电动色谱分离-毛细管电泳法测定升麻中三种有机酸含量

采用电场增强胶束扫集-电动色谱-毛细管电泳法对升麻中异阿魏酸、阿魏酸和咖啡酸的含量进行了测定,电泳缓冲体系为90 mmol·L~(-1)SDS-20 mmol·L~(-1)NaH_2PO_4(pH 2.20)-甲醇(10+90),分离电压为20 kV,检测波长214 nm。在优化的试验条件下,胶束扫集-电动色谱法对异阿魏酸、阿魏酸和咖啡酸富集倍数为4.3,4.8,2.9,3种有机酸均在14 min内出峰,线性范围分别为0.50～20.0,0.50～20.0,1.0～40.0 mg·L~(-1)。应用此方法分析了升麻样品并进行了回收率和精密度试验,测得回收率在93.2%～113.3%之间,测定值的相对标准偏差(n=5)小于6%。     

Determination of ephedrine and codeine in human urine by cation-selective exhaustive injection and sweeping micellar electrokinetic chromatography

A sensitive method for the determination of ephedrine and codeine in human urine by capillary electrophoresis(CE)was described.In order to improve the sensitivity,two online concentration techniques including cation-selective exhaustive injection (CSEI)and sweeping micellar electrokinetic chromatography(sweeping-MEKC)were used.Under the optimum conditions,the detection limits(S/N=3)were 0.10μg/L for ephedrine and 0.80μg/L for codeine.This method was successfully applied to real urine sample analysis.     

Determination of ephedrine alkaloid stereoisomers in dietary supplements by capillary electrophoresis

Three complementary capillary electrophoresis (CE) methods were developed for the separation and quantification of ephedrine and pseudoephedrine stereoisomers. Either single or dual cyclodextrin-based chiral selector systems provided enantioselective separation of the compounds of interest. The three methods were applied to the analysis of a suite of five standard reference materials (SRMs) containing ephedra. Use of a high-sensitivity UV detection cell enhanced quantification of the analytes of interest over the wide range of concentrations encountered in the SRMs. Results for (-)-ephedrine ranged from 0.31 to 76.43 mg/g, and for (+)-pseudoephedrine ranged from 0.049 to 9.23 mg/g in the materials studied. Results from the three methods agreed well with each other and with the results from other methods of analysis. The addition of known amounts of specific enantiomers was used to confirm the enantiomeric identity of the analytes. The results obtained by the three CE methods were utilized for value assignment of the ephedrine alkaloid content of these five SRMs.     

Determination of piribedil in pharmaceutical formulations by micellar electrokinetic capillary chromatography

A fast and simple micellar electrokinetic capillary chromatographic method was developed for the analysis of piribedil in pharmaceutical formulations. The effects of buffer concentration, buffer pH, sodium dodecyl sulphate (SDS) concentration, organic modifier, applied voltage and injection time were investigated. Optimum results were obtained with a 50 mM borate buffer at pH 8.0 containing 50 mM SDS by using a fused silica capillary (50 m internal diameter, 72 cm effective length). The sample was injected hydrodynamically for 4 s at 50 mbar pressure and the applied voltage was +30 kV. The detection wavelength was set at 205 nm. Diflunisal was used as an internal standard. The analysis was performed at 25 °C and the total run time was 14 min. The method was suitably validated with respect to linearity range, limit of detection and quantification, precision, accuracy, specificity and robustness. The linear calibration range was 5–100 g mL^–1 and the limit of detection was determined as 1 g mL^–1. The method developed was successfully applied to the determination of piribedil in pharmaceutical formulations. The results were compared with a spectrophotometric method reported in the literature and no significant difference was found statistically.     

Simultaneous analysis of polyhydroxylated alkaloids by capillary electrophoresis using borate complexation and evaluation of sweeping technique for sensitivity improvement

Summary Capillary zone electrophoresis coupled to UV detection was used for the simultaneous analysis of naturally occurring polyhydroxylated alkaloids. This separation was based on anin-situ complexation with borate ions. The effect of parameters such as borate concentration, capillary temperature and analyte molecular structure on migration times and selectivity were discussed. The best separation was obtained with a fused silica capillary (48.5 cm total length ×50 μm I.D., with a bubble factor of 3), 80 mM sodium tetraborate aqueous solution at pH 9.2 and temperature of 20°C. The method was validated and showed good data in terms of migration time and peak area reproducibility, selectivity, linearity and accuracy. The validated method was applied to determine miglitol in commercially available pharmaceutical tablets. To further improve method sensitivity, a sweeping technique involving borate ions was evaluated. This technique was found very sensitive to the analyte complexation with borate, borate concentration, and temperature as well as sample matrix. In the case of miglitol, a 35-fold improvement in peak height was achieved.     

胶束毛细管电泳在线扫集技术同时分离测定穿心莲内酯和脱水穿心莲内酯的研究

采用胶束毛细管电泳在线扫集技术分离测定了中药穿心莲中脱水穿心莲内酯和穿心莲内酯.电泳条件:以20 mmol/L H3BO310 mmol/L NaH2PO4-50mmol/L SDS(含体积分数20%甲醇,pH 2.4)为电泳运行缓冲溶液,未涂层石英毛细管(58 cm×50 μm i.d.,有效长度为41.2 cm)为分离通道,重力进样,进样高度为11 cm,-20 kV恒压,检测波长为246 nm.富集倍数可以达到200倍以上.在5.70～91.20 mg/L,和3.96～31.68 mg/L范围内呈良好的线性关系,对两种内酯分别进行了定量分析.加标平均回收率脱水穿心莲内酯为100.80%,穿心莲内酯为98.06%.