六味地黄丸的串联双检测器高效液相色谱分析

采用紫外检测器与蒸发光散射检测器串联的方式构建了高效液相色谱分析系统,并用于对六味地黄丸的分析研究。紫外检测器共检测到26个色谱峰;蒸发光散射检测器检测到31个色谱峰,其中15个色谱峰为可以认证的共有峰。所构建的系统适宜于中草药的指纹图谱研究。     

高效液相色谱-蒸发光散射检测法测定肉苁蓉中的甜菜碱

建立了高效液相色谱-蒸发光散射检测法测定中药材肉苁蓉中甜菜碱含量的方法。采用Waters Spherisorb S5 NH2 色谱柱(250 mm×4.6 mm, 5 μm),柱温25 ℃,流动相为0.1%（体积分数）三氟乙酸水溶液-甲醇(体积比为15∶85）,流速0.6 mL/min。蒸发光散射检测器参数：漂移管温度90 ℃,喷雾器温度45 ℃,载气（氮气）压力110 kPa（16 psi）。结果表明,该法具有良好的线性关系,同时,不同种肉苁蓉的测定结果表明：管花肉苁蓉不含甜菜碱,因此建议将甜菜碱作为标志物质来鉴别正品肉苁蓉(Cistanche deserticola Y. C. Ma)和管花肉苁蓉(C. tubulosa (schenk) R. Wight)。     

超高效亲水作用色谱-蒸发光散射检测牛磺酸颗粒和牛磺酸滴眼液中牛磺酸的含量

建立了超高效亲水作用色谱-蒸发光散射(UP-HILIC-ELSD)检测牛磺酸颗粒和牛磺酸滴眼液中牛磺酸含量的方法.样品采用乙腈-水稀释,在超高效酰胺基(Amide)亲水作用色谱柱中分离,乙腈-水为流动相,梯度程序洗脱,蒸发光检测器测定.牛磺酸绝对质量在2.5～100 ng时浓度与峰面积响应呈良好的线性关系,相关系数(r...     

微流蒸发光散射检测器的研制及评价

构建了适用于纳升级到微升级流量的毛细管分离体系的微流蒸发光散射检测器(μELSD),实现了其与毛细管液相色谱(eLC)的联用.对雾化器孔径和雾化毛细管内径、蒸发管内径和长度、光散射池尺寸、雾化毛细管位置和辅助载气流量等参数进行了优化.在最优条件下,微流蒸发光散射检测器检出限为直接进样葡萄糖1 ng(S/N＞ 10),线性范围0.01～1.0 μg,重复性好,峰面积RSD(n=6)为0.4％,峰高RSD(n=6)为0.3％.本检测器已成功应用cLC-μELSD平台,使用C18毛细管色谱柱(内径250 μm),0.1％甲酸铵溶液(pH 4.5)-甲醇(60∶40,V/V)为流动相,分离检测了3种常用甜味剂,表明本研究构建的系统可以应用于实际分离检测中,具有分析时间快、溶剂消耗量少、样品需求量小的优点.     

反相离子对色谱/蒸发光散射检测器分离唑来膦酸及其有关物质

采用反相离子对高效液相色谱／蒸发光散射检测法研究了唑来膦酸及其有关物质的色谱分析与分离方法。优化了色谱条件，固定相为Hypersil C8柱，以含10 mmol／L正戊胺的5mmol／L乙酸铵缓冲液（用乙酸调节pH至7．0）-甲醇（体积比为97：3）为流动相，流速为1．0mL/min，蒸发光散射检测器检测。在该色谱条件下，唑来膦酸与其有关化合物（包括合成过程中残余的原料咪唑乙酸及分解产物亚磷酸、磷酸盐）的分离良好，唑来膦酸色谱峰与最近杂质峰的分离度大于1．5。本法简便快速，为唑来膦酸的常规分析提供了有效可靠的方法。     

高效液相色谱-蒸发光散射检测法测定玉屏风胶囊中黄芪甲苷的含量

建立高效液相色谱-蒸发光散射检测法测定玉屏风胶囊中黄芪甲苷的含量.采用Phenomenex C18(4. 6mm×250 mm i. d. ,5μm)色谱柱,柱温为35℃,以乙腈-水(35∶65)为流动相,以蒸发光散射检测器进行检测.以峰面积的常用对数(Y)对进样量的常用对数(X)进行线性回归,回归方程为Y=1. 6709 X+14. 2699(r=0. 9998),线性范围为1～19μg.加标回收率为86. 7%～96. 2%,测定结果的RSD为0. 22%(n=7).方法准确、可靠、重复性好,可有效控制玉屏风胶囊的质量.     

应用高效离子交换色谱快速分离定量不同致病力的青枯菌

应用高效离子交换色谱和激光光散射仪在线检测,快速分离定量不同致病力的青枯菌。青枯菌经过高效离子交换色谱分离得到3个特征峰,通过2,3,5-三苯基氯化四氮唑(TTC)平板鉴定和采用剪叶法回接番茄组培苗感染试验,发现这3个色谱峰所对应的青枯菌在致病力方面存在差异;其中峰3组分的致病力最强,峰1组分的致病力最弱。通过对青枯菌进样量与激光光散射仪的响应信号(峰面积)之间的线性关系研究,发现当青枯菌进样菌数为9×106~9×108时,菌数与色谱峰面积之间呈现出良好的线性关系,相关系数r=0.99。该项应用研究为不同致病力青枯菌的快速定量提供了一种新的分析方法。     

抗生素功能化金磁纳米探针的制备及其过氧化物模拟酶性能研究

以抗生素替考拉宁(Teicoplanin, Teico)作为还原剂和稳定剂,还原吸附在羧基化四氧化三铁纳米粒子(Fe_3O_4)表面的氯金酸根离子(AuCl_4~-),常温(25℃)下制备得到抗生素功能化金磁纳米探针(Teico-Au-Fe_3O_4).通过紫外-可见光谱法、透射电子显微镜、能量色散光谱法、动态光散射等方法对所得抗生素功能化金磁纳米探针的形貌、结构、光学性质等进行表征,并研究了其生物活性及过氧化物模拟酶催化性能.结果表明,该探针对金黄色葡萄球菌(Staphylococcus aureus, S.aureus)有明显的抑菌活性,同时该探针具有过氧化物模拟酶催化活性,对酶底物3,3′,5,5′-四甲基联苯胺(tetramethylbenzidine, TMB)的米氏常数Km为0.879 mM;基于其生物活性及过氧化物模拟酶催化活性可初步应用于检测S.aureus.     

亲水色谱-蒸发光散射检测器定量分析白坚木皮醇含量

建立白坚木皮醇(Quebrachitol)含量的亲水作用色谱-蒸发光散射检测器(ZICHILIC-ELSD)测定方法。Merck ZIC-HILIC色谱柱(150×4.6mm,5μm);以乙腈-水(体积比为70∶30)为流动相,等度洗脱,流速为1.0mL/min;蒸发光散射检测器,蒸发温度为65℃,雾化温度为50℃,高纯氮压力9.9 MPa。结果表明,白坚木皮醇浓度与其色谱峰面积积分值呈很好的线性关系,相关系数为0.9997。检测限为0.08mg/mL;相对标准偏差为0.48%;加标回收率为100.3%。该方法快速、简便、准确,适合从复杂体系中快速检测白坚木皮醇的含量。     

高效液相色谱-蒸发光散射检测法直接检测20种未衍生基本氨基酸

应用国产蒸发光散射检测器(ELSD),建立了一种采用反相高效液相色谱-蒸发光散射检测器(RHPLC-ELSD)直接测定20种未衍生基本氨基酸的分析方法,并将其用于氨基酸注射液中氨基酸含量的测定。采用BISCHOFFTM　C18 AQ PLUS色谱柱(250 mm×4.6 mm, 5 μm)分离,以甲醇-0.2%七氟丁酸溶液(含0.1%三氟乙酸)为流动相进行梯度洗脱,流速0.8 mL/min,ELSD飘移管温度40 ℃,载气流量2.5 L/min,对20种基本氨基酸进行分离检测。氨基酸的质量浓度在30～300 mg/L范围内,其峰面积的对数值与进样质量的对数值呈良好的线性关系;氨基酸的检出限(信噪比(S/N)＞3)介于24 ～100 ng之间,样品加标回收率为90.6%～106.0%。结果表明,该系统及方法操作简便快速、准确可靠,无需依靠专门的氨基酸分析仪或衍生处理氨基酸即可直接测定氨基酸注射液中氨基酸含量,为药品、食品及化工生产等领域混合氨基酸样品的直接检测提供了参考。     

Determination of thyroid hormones in pharmaceutical preparations,after derivatization with 9-anthroylnitrile,by high-performance liquid chromatography with fluorescence detection

Fast ion-exchange chromatography has been developed and applied to the separation of common inorganic anions. Using a didodecyldimethylammonium bromide (DDAB) coated short (30 mm x 4.6 mm) ODS analytical column (3-microm particle size) and a 5 mM phthalate eluent (pH 7.5) the isocratic separation of nine common anions in 160 s was possible, with the first seven anions, including phosphate, chloride and sulphate, separated within 65 s. Detection was achieved using indirect UV at 279 nm. The high capacity, highly hydrophobic ion-exchange coating demonstrated excellent stability over time, even at elevated temperatures (45 degrees C) and exhibited unusual selectivity for common anions (retention order=fluoride, carbonate, phosphate, chloride, bromate, nitrite, sulphate, bromide and nitrate). The developed chromatography was successfully applied to the rapid analysis of river water and seawater samples.     

Column Switching Technique for Group-Type Separation of Different Pah Classes by use of C18-Modified Silica and Polystyrene Packings

Abstract

A column switching technique was developed to realize a group-type separation of PAHs and nitrogen containing PAHs (N-PAHs) applying a C₁₈-immobilized polystyrene packing as well as a C₁₈-modified silica stationary phase. On the first column the group-type separation and also the separation of the N-PAH fraction in single compounds was performed. After backflush and transfer to a second column, the separation of the PAH fraction could be achieved.     

Rapid detection of Staphylococcus aureus by a combination of monoclonal antibody-coated latex and capillary electrophoresis

The rapid detection of pathogenic bacteria is extremely important in biotechnology and clinical diagnosis. CE has been utilized in the field of bacterial analysis for many years, but to some extent, simultaneous separation and identification of certain microbes from complex samples by CE coupled with UV detector is still a challenge. In this paper, we propose a new strategy for rapid separation and identification of Staphylococcus aureus (S. aureus) in bacterial mixtures by means of specific mAb-coated latex coupled with CZE. An appropriate set of conditions that selectively isolated S. aureus from the microorganisms Escherichia coli, Pseudomonas aeruginosa, and Klebsiella pneumoniae were established. S. aureus could be differentiated from the others by unique peaks in the electropherograms. The validity was also confirmed by LIF with antibodies specific to both the latex and the microbial cells. The LOD is as low as 9.0 x 10(5) colony forming unit/mL. We have also utilized this technology to identify S. aureus in a stool sample coming from a healthy volunteer spiked successfully with S. aureus. This CZE-UV technique can be applied to rapid diagnosis of enteritis caused by S. aureus or other bacterial control-related fields needing rapid identification of target pathogens from microbial mixtures. In theory, this method is suitable for the detection of any bacterium as long as corresponding bacterium-specific antibody-coated latex is available.     

A vacuum assisted dynamic evaporation interface for two-dimensional normal phase/reverse phase liquid chromatography

A vacuum assisted dynamic solvent evaporation interface for coupling of two-dimensional normal phase/reverse phase liquid chromatography was developed and evaluated. A normal-phase liquid chromatographic (NPLC) column of a 250 mm × 4.6 mm I.D. 5 μm CN phase was used as the first dimension, and a reversed-phase liquid chromatographic (RPLC) column of 250 mm × 4.6 mm I.D. 5 μm C₁₈ phase was used as the second dimension. The eluent from the first dimension flowed into a fraction loop, and the solvent in the eluent was dynamically evaporated and removed by vacuum as it was entering the fraction loop of the interface. The non-evaporable analytes was retained and enriched in about 5–25 μL solution within the loop. Up to 1 mL/min of mobile phase from the first dimension can be evaporated and removed dynamically by the interface. The mobile phase from the second dimension then entered the loop, and dissolved the concentrated analytes retained inside the loop, and carried them onto the second dimension column for further separation. The operation conditions of the two dimensions were independent from each other, and both dimensions were operated at their optimal chromatographic conditions. We evaluated the interface by controlling the loop temperature in a water bath at normal temperature, and investigated the sample losses by using standard samples with different boiling points. It was found that the sample loss due to evaporation in the interface was negligible for non-volatile samples or for components with boiling point above 340 °C. The interface realizes fast solvent removal of mL volume of fraction and concentration of the fraction into tenth of μL volume, and injection of the concentrated fraction on the secondary column. The chromatographic performance of the two-dimensional LC system was enhanced without compromise of separation efficiency and selectivity on each dimension.     

正相模式/反相模式的二维液相色谱系统的构建与应用

以4.6mm×50 mm i. d.的Hypersil SiO2正相色谱柱为第一维,4.6mm×250 mm i. d.的Kromasil C18反相色谱柱为第二维,通过升高第二维色谱温度的方法增加两维流动相间互溶性的方法构建了定量环-阀切换接口的二维液相色谱系统(NPLC×RPLC)。根据有机溶剂的特征,在第一维正相色谱流动相中加入二氧六环;第二维反相色谱流动相中加入异丙醇,在改善流动相兼容性的同时,有效调整分离选择性。采用此系统对正天丸样品进行分离分析,达到1120的峰容量。     

Fast determination of anions on a short coated column

In this paper, a simple method for the separation and determination of common inorganic anions by fast ion-exchange chromatography, using a modified short (25 mm x 4.6 mm) monolithic column, is reported. Coating the column with a cationic surfactant, cetylpyridinium chloride (CPC), the isocratic separation of some inorganic anions in minutes was possible, by direct or indirect UV detection. The coated column demonstrated excellent stability over time, even at a high flow-rate, giving retention times with an average relative standard deviation of 1.3% for over 10 consecutive runs. The developed column exhibited unusual selectivity for common anions, was successfully applied to the rapid analysis of inorganic anions of food samples, river water and factory waste water samples.     

Separation of urine proteins on the anion-exchange resin mono Q

Proteins excreted in urine due to renal failure were separated on Mono Q, a new strong anion exchange designed for fast high-resolution protein separations. The separation procedure was divided into two steps. The first step involved removal of low-molecular-weight substances by rapid desalting on a Sephadex G-25 Superfine column. In the second step, the total protein fraction (3--6 ml) was loaded onto the Mono Q column with the aid of a superloop. The proteins were adsorbed onto the top of the ion-exchanger column and gradually displaced by a combined pH and salt gradient in 40 min. The choice of ion exchanger and initial operating conditions were based on data obtained from electrophoretic titration curve experiments. Identification of separated proteins was achieved by fused rocket electrophoresis and sodium dodecyl sulphate-polyacrylamide gel electrophoresis, respectively.     

Affinity cryogel monoliths for screening for optimal separation conditions and chromatographic separation of cells

Suitable conditions for separating cells using a chromatographic procedure were evaluated in parallel chromatography on minicolumns. A 96-hole minicolumn plate filled with cryogel monoliths (18.8 mm x 7.1 mm ?) with immobilized concanavalin A was used. Chromatographic columns (113 mm x 7.1 mm ?) were used for chromatographic resolution of a mixture of Saccharomyces cerevisiae and Escherichia coli cells. Separation of a cell mixture containing equal amounts of cells of both types performed in a column format under the determined optimal conditions, resulted in a quantitative capture of applied S. cerevisiae cells, while E. coli passed through the column. Bound S. cerevisiae cells were released by flow-induced detachment and by compression of the adsorbent in the presence of 0.3 M methyl alpha-D-manno-pyranoside. The flowthrough and the eluted fractions were analyzed by plate counting and by registering metabolic activity of S. cerevisiae cells in the eluted fractions after capturing on ConA-cryogel monoliths in a 96-minicolumn plate format. The flowthrough fraction contained E. coli cells with nearly 100% purity, whereas the fraction eluted by compression of the adsorbent contained viable S. cerevisiae cells with 95% purity. Thus, an efficient chromatographic separation of cells was achieved using affinity cryogel column.     

Stroboscopic sampling in comprehensive high-performance liquid chromatography-capillary electrophoresis via a pneumatic sampler

A new approach is presented to solve the problem of a long separation time in the second dimension of comprehensive two-dimensional chromatography. The need for a rapid separation in the second column is overcome by repeating analysis of a sample many times. In each of these individual analysis cases the sample is injected into the first dimension column and after a delay a low amount of the effluent at the end of the first column is sampled to the second-dimensional column. The time interval between the samplings from the first column to the second column is constantly increased. Thus, the system enables a comprehensive analysis of the effluent emerging from the first into the second column. This approach, which we call stroboscopic sampling, is tested for coupling high-performance liquid chromatography (HPLC) to capillary electrophoresis (CE) by an interface which operates on the principle of transporting the effluent from the HPLC column to the capillary inlet by small pressure pulses (0.5 MPa). The performance of the interface for accomplishing the comprehensive HPLC-CE analysis was demonstrated for an on-line connection of a short ion-exchange column and an ion-exclusion column to the CE capillary.     

Employing ultra high pressure liquid chromatography as the second dimension in a comprehensive two-dimensional system for analysis of Stevia rebaudiana extracts

Stevia rebaudiana extracts and plant materials are increasingly used as natural sweeteners. Polyphenolic and stevioside compounds contained in S. rebaudiana extracts were separated by comprehensive LC. A polyamine column operated in normal phase mode was used for the first dimension separation (D1), and a UHPLC C18 column operated in reversed phase mode was used for the second dimension separation (D2). The sub-2 μm column (2.1 mm × 30 mm, maintained at 70°C) and the UHPLC pump employed for D2 elution allowed a separation/cycle time of 20 s, with a backpressure oscillating between 805 and 922 bar at 3.4 mL/min. The reduced D2 cycle time allowed 3-12 D2 samplings for each peak eluted by D1. Polyphenolic and stevioside compounds were identified by combining the information coming from the position of the compounds in the 2D plot and UV spectra with that of reference materials.