毛细管电泳法测定紫草中的紫草素

建立了毛细管电泳高频电导法测定紫草药材中左旋紫草素含量的分析方法。以融硅毛细管(150μm×70 cm)为分离柱,研究了缓冲液的种类、浓度、添加剂种类与添加量、分离电压和进样量等因素对分离和检测的影响,优化选择1.0 mmol/L H3BO3 3.0 mmol/L三乙胺缓冲液为电泳介质,分离电压18.0 kV,可实现分离检测。在优化条件下左旋紫草素线性范围为10.0~250 mg/L;线性相关系数为0.9962;检出限为5.0 mg/L(S/N=3)。2批样品不同浓度添加水平的日内和日间RSD均小于4%,两批药材的加标回收率分别为93.9%~97.4%和93.1%~101%。该方法简便、快速、灵敏度高,可以用于紫草药材的质量控制。     

毛细管电泳法测定复方制剂中的硝酸咪康唑

毛细管电泳;高频电导检测;非接触式电导检测;硝酸咪康唑;复方制剂     

基于非接触式电导信号的土壤速效钾含量检测方法

该文针对土壤中速效钾含量采用传统测定法操作复杂、检测时效滞后的问题,建立了基于非接触式电导检测信号快速检测土壤速效钾含量的分析方法。采用高效毛细管电泳/非接触式电导检测仪获取河南潮土的非接触式电导检测信号,并使用导数法与高斯曲线拟合法相结合进行初步峰谱识别,按条件进行峰值过滤后,引入基于Levenberg-Marquardt(L-M)的高斯分峰拟合算法,实现了单峰和重叠峰的拟合计算,得到高斯峰和相应的特征参数,包括峰位、峰高、半峰宽和峰面积;最后将拟合得到的高斯峰及相应的特征参数表征原始非接触式电导检测信号离子峰谱信息结合偏最小二乘法(PLS),确定特征参数与土壤速效钾含量的关系,建立模型,实现了对土壤中速效钾含量的预测。结果表明,将基于L-M的高斯分峰拟合算法结合偏最小二乘法应用于非接触式电导检测信号测定土壤速效钾含量时具有较高精度,回归模型决定系数(R²)为0.856 4,相对分析误差(RPD)为2.639,适用于土壤速效钾的快速检测分析。     

Application of capillary electrophoresis with capacitively coupled contactless conductivity detection (CE‐C4D): An update

Capacitively coupled contactless conductivity detection (C⁴D) has appeared as a powerful technique for the detection of compounds lacking chromogenic or fluorogenic group. Since our last review (Biomedical Chromatography 2014; 28 : 1502–1506) several new capillary electrophoresis (CE)‐C⁴D methods have been reported. This review provides an update of the most recent utilization of CE‐C⁴D in the field of pharmaceutical, biomedical and food analysis covering the period from February 2014 to October 2016. The use of CE with C⁴D in the pharmaceutical field has been shown in many papers. Examples illustrate the applicability of CE‐C⁴D in the fields of pharmaceutical, biomedical and food analysis. Finally, general conclusions and perspectives are provided.     

A voltage trade study for the design of capillary electrophoresis instruments for spaceflight

Capillary electrophoresis (CE) systems have undergone extensive development for spaceflight applications. A flight-compatible high voltage power supply and the necessary voltage isolation for other energized components can be large contributors to both the volume and mass of a CE system, especially if typical high voltage levels of 25–30 kV are used. Here, we took advantage of our custom CE hardware to perform a trade study for simultaneous optimization of capillary length, high voltage level, and separation time, without sacrificing method performance. A capillary electrophoresis with capacitively coupled contactless conductivity detection (CE-C⁴D) method recently developed by our group to target inorganic cations and amino acids relevant to astrobiology was used as a test case. The results indicate that a 50 cm long capillary with 15 kV applied voltage (half of that used in the original method) can be used to achieve measurement goals while minimizing instrument size.     

Optimized hybrid dielectrophoretic microchip for separation of bioparticles

Point-of-care diagnostics requires a smart separation of particles and/or cells. In this work, the multiorifice fluid fractionation as a passive method and dielectrophoresis-based actuator as an active tool are combined to offer a new device for size-based particle separation. The main objective of the combination of these two well-established techniques is to improve the performance of the multiorifice fluid fractionation by taking advantage of dielectrophoresis-based actuator for separating particles. Initially, by using numerical simulations, the effect of using dielectrophoresis-based actuator in multiorifice fluid fractionation on the separation of particles was investigated, and the size of the device was optimized by 25% compared to a device without dielectrophoresis-based actuator. Also, adding dielectrophoresis-based actuator to multiorifice fluid fractionation can extend the range of flow rates needed for separation. In the absence of dielectrophoresis-based actuator, the separation took place only when the flow rate is 100 μL/min, in the presence of dielectrophoresis-based actuator (20 Vp-p), the separation happened in flow rates ranging from 70 to 120 μL/min.     

Capacitively coupled contactless conductivity detection as an alternative detection mode in CE for the analysis of kanamycin sulphate and its related substances

A method was developed to determine simultaneously kanamycin, its related substances and sulphate in kanamycin sulphate using capacitively coupled contactless conductivity detection. Kanamycin is an aminoglycoside antibiotic that lacks a strong UV-absorbing chromophore. Due to its physicochemical properties, CE in combination with capacitively coupled contactless conductivity detection was chosen. The separation method uses a BGE composed of 40 mM 2-(N-morpholino)ethanesulphonic acid monohydrate and 40 mM L-histidine, pH 6.35. A 0.6 mM N-cetyltrimethyl ammonium bromide (CTAB) solution was added as electroosmotic flow modifier in a concentration below the critical micellar concentration (CMC). Ammonium acetate 50 mg/L was used as internal standard. In total, 30 kV was applied in reverse polarity on a fused-silica capillary (65/41 cm; 75 μm id). The optimized separation was obtained in less than 6 min with good linearity (R(2)=0.9999) for kanamycin. It shows a good precision expressed as RSD on the relative peak areas equal to 0.3 and 1.1% for intra-day and inter-day precision, respectively. The LOD and LOQ are 0.7 and 2.3 mg/L, respectively. Similarly, for sulphate, a good linearity (R(2)=0.9996) and precision (RSD 0.4 and 0.6% for intra-day and inter-day, respectively) were obtained.     

微流控芯片测定盐酸地芬尼多片中盐酸地芬尼多

利用微流控芯片非接触电导检测法测定片剂中盐酸地芬尼多的含量.采用1 mmol/L HAc+2 mmol/L NaAc(pH 4.5)为缓冲溶液,0.2 mmol/L 十二烷基硫酸钠(SDS)为添加剂,在分离电压为2.20 kV,进样时间为10 s下,1 min内实现组分快速分离和检测.盐酸地芬尼多线性范围为5～160 ...     

微流控芯片非接触电导检测法测定药片中盐酸奈福泮

建立了微流控芯片非接触电导检测法测定片剂中盐酸奈福泮含量的方法.探讨并优化了缓冲溶液种类和配比、添加剂、分离电压和进样时间等电泳分离条件.结果表明,以2mmol/L HAc+1mmol/L NaAc( pH4.5)不加添加剂为运行缓冲溶液,分离电压2.00 kV、进样时间10 s时,1min内可实现盐酸奈福泮快速分离检...     

Microwire formation based on dielectrophoresis of electroless gold plated polystyrene microspheres

Microspheres coated with a perfectly conductive surface have many advantages in the applications of biosensors and micro-electromechanical systems.Polystyrene microspheres with the diameter of 10 μm were coated with a 50 nmthick gold layer using an electroless gold plating approach.Dielectrophoresis(DEP) for bare microspheres and shelled microspheres was theoretically analysed and the real part of the Clausius-Mossotti factor was calculated for the two kinds of microspheres.The experiments on the dielectrophoretic characterisation of the uncoated polystyrene microspheres and gold coated polystyrene microspheres(GCPMs) were carried out.Experimental results showed that the gold coated polystyrene microspheres were only acted by a positive dielectrophoretic force when the frequency was below 40M Hz,while the uncoated polystyrene microspheres were governed by a negative dielectrophoretic force in this frequency range.The gold coated polystyrene microspheres were exploited to form the microwire automatically according to their stable dielectrophoretic and electric characterisations.