射干的毛细管电泳指纹图谱研究

采用毛细管区带电泳法,以80 mmol/L硼酸-15 mmol/L硼砂缓冲液(用氢氧化钾溶液调pH 9.7)为背景电解质,运行电压12.1 kV,检测波长228 nm,重力进样10 s(高度7 cm),建立了射干药材的毛细管电泳指纹图谱(CEFP)。标定CE指纹峰为21个,方法的精密度和重现性较好,相对迁移时间的相对标准偏差(RSD)不大于3.5%, 相对峰面积的RSD约为5.0%,10个产地样品的CEFP与标准CEFP的相似度为0.913～0.993。同时,对指纹图谱中各指纹峰确立的方法和各组分含量情况     

连翘的毛细管电泳指纹图谱研究

采用毛细管区带电泳法,以75 mmol/L硼砂溶液(用0.1 mmol/L氢氧化钠溶液调pH 9.7)为背景电解质,运行电压14 kV,检测波长228 nm,重力进样15 s(高度9 cm),建立了连翘药材的毛细管电泳指纹图谱(CEFP)。将10个不同产地的连翘药材进行比较,按各电泳峰共有率fi≥70%作为选择电泳指纹峰的依据,确定连翘的毛细管电泳指纹峰为29个。在方法的精密度和重复性试验中,各指纹峰的相对迁移时间的相对标准偏差(RSD)不大于5%,相对峰面积的RSD约为2%~15%。10个产地的连翘药材的CEFP与其对照CEFP的相似度均不低于0.94。同时,采用指纹图谱信息量指数I和相对信息量指数Ir评价了10个产地连翘药材的质量差异。     

三角形法和四面体法优化选择毛细管区带电泳背景电解质

建立了两种高效、快速的毛细管区带电泳背景电解质(BGE)的优化方法三角形优化法和四面体优化法。以色谱指纹图谱指数F和色谱指纹图谱相对指数Fr作为评价毛细管电泳分析系统的目标函数,以雪莲药材水提取液为样品,考察一定浓度的硼砂、硼酸、磷酸氢二钠和磷酸二氢钠溶液按三角形优化法和四面体优化法构成背景电解质时对样品的分离情况,通过添加有机改性剂和调节pH进行再优化。用三角形法优化出以50 mmol/L硼砂-含3%乙腈的150 mmol/L磷酸二氢钠(体积比为1∶1)作为BGE时分离效果最佳,用四面体法优化出以50 mmol/L硼砂-150 mmol/L磷酸二氢钠-200 mmol/L硼酸(体积比为1∶1∶2,用0.1 mol/L氢氧化钠调pH 8.55)作为BGE时分离效果最佳,分别获得28个和25个电泳峰。所建立的方法操作简捷,适用于中药材水提取液或醇提取液的毛细管区带电泳BGE的选择。     

大青叶的毛细管电泳指纹图谱研究

采用高效毛细管电泳法,紫外检测波长228nm,电压12．5kV,以硼酸(100mmol／L)：硼砂(50mmol／L)=11：10(调pH11)为背景电解质进行指纹图谱研究。建立了大青叶药材的电泳指纹图谱(CEFP)。以胞苷峰为参照物峰,确定了18个共有峰,测定了10个产地大青叶的CEFP与共有模式间具有良好的相似性,用色谱指纹图谱指数对其进行评价。所建立的CEFP具有较好的重现性,可用于大青叶药材的质量控制。     

新疆紫草的毛细管电泳指纹图谱研究

建立了基于毛细管电泳技术的新疆紫草指纹图谱的质量控制方法.优化后的电泳条件:分离柱为50μm×40 cm未涂层毛细管柱,运行缓冲液为pH 8.0、100 mmol/L硼酸盐缓冲液(含25 mmol/L SDS及20%(V/V)无水乙醇),进样量0.5 psi×5 s,分离电压25 kV,检测波长214 nm.应用此条件,35 min内可实现新疆紫草有效成分的高效分离.在方法学验证的基础上,建立了新疆紫草指纹图谱.以新疆紫草对照药材指纹图谱为对照图谱,通过特征指纹峰、SFˊ相似度评价、聚类分析对不同购买地的新疆紫草进行质量评价和鉴别.此研究结果与其它中药鉴定方法对照结果一致.本方法准确、可靠、用时短,且具有良好的重现性,为新疆紫草的质量控制与评价提供了一种新的快速有效的鉴别方法.     

应用毛细管区带电泳测定人血清蛋白

摘要：研究了一种用于临床检测血清蛋白的毛细管区带电泳方法。弹性石英毛细管50μmi.d.×47cm（40cm有效长度）,检测波长200nm,血清用运行缓冲液（含12.5mmol/L四硼酸钠、1mmol/L乳酸钙、0.7mmol/L硫酸镁,pH9.70）稀释40倍,气压进样17.23kPa·s,分析电压23kV。正常血清蛋白分为6种,孕妇的分7种（多一个未知的α0峰）。将正常人、孕妇、多发性骨髓瘤和强直性脊柱炎患者的血清蛋白的毛细管电泳与传统的醋酸纤维膜电泳相比较,前者具有高分辨率、在线数据处理和自动化的特     

金银花的毛细管电泳指纹图谱研究

采用毛细管区带电泳法,以50 mmol/L硼砂(含20 mmol/L β-环糊精(CD),用磷酸调pH 8.0)为背景电解质,运行电压12 kV,紫外检测波长254 nm,重力进样15 s（高度8.5 cm）,建立了金银花药材水提取液的毛细管电泳指纹图谱(CEFP)。将13个不同产地的金银花药材供试液的CEFP进行比较,以电泳峰出现率100%计,确定金银花的共有指纹峰为18个。该CEFP具有较好的精密度和重现性,分离效能高且成本低廉。提出了指纹图谱宏观含量相似度R、投影含量相似度C和定量相似度P的概念,可从总体上评价药材化学组分的整体含量情况。从两个方面评价各产地药材与对照CEFP间的总体相似性,合格药材应具备以下两个条件：(1)代表化学成分分布相似性的定性相似度(S)≥0.90;(2)描述药材整体化学成分含量的定量相似度(R,C,P,Q)应在80%～120%。以此二类相似度指标控制金银花的质量,建立了指纹图谱评价的又一新方法。     

逍遥丸的毛细管电泳指纹图谱的建立

采用毛细管区带电泳法建立了逍遥丸(Xiaoyao Pill, XYP)的毛细管电泳指纹图谱(CEFP)。运用正方形优化法,以色谱指纹图谱分离量指数(RF)为优化的目标函数,对建立指纹图谱的实验条件进行了优化,确定了最佳背景电解质(BGE)溶液50 mmol/L硼砂-50 mmol/L磷酸氢二钠-150 mmol/L磷酸二氢钠-50 mmol/L碳酸氢钠(1:1:1:5, v/v/v/v; pH 7.40)、紫外检测波长228 nm、运行电压12 kV、重力进样25 s (高度14 cm)的分离检测条件。采用未涂层石英毛细管(70 cm×75 μm,有效分离长度57 cm)分离,以咖啡酸色谱峰为参照,确定13批逍遥丸样品的21个共有指纹峰。通过聚类分析确定用其中10批样品生成对照CEFP,以此为标准用系统指纹定量法鉴别13批逍遥丸的质量,结果显示: S3号样品的化学成分数量和分布比例不合格,S10和S12号样品含量明显偏高,其余批次质量均合格。所建立的正方形优化法操作简便,适用于中药的毛细管区带电泳BGE的选择;所建立的逍遥丸CEFP具有较好的精密度和重现性,可以为逍遥丸的质量控制提供新的参考。     

柏子养心丸的毛细管电泳指纹图谱

建立了柏子养心丸(Baizi Yangxin Wan, BZYXW)毛细管区带电泳指纹图谱(CEFP)。采用三棱柱优化法优化背景电解质(BGE),以色谱指纹图谱分离量指数(RF)为实验条件优化的目标函数,最终确定BGE为50 mmol/L硼砂-50 mmol/L磷酸氢二钠-200 mmol/L硼酸-150 mmol/L碳酸氢钠(体积比为7:7:1:1,含4%乙腈,pH 9.70)。在其他优化的毛细管电泳条件为紫外检测波长228 nm,运行电压12 kV,重力进样25 s (高度14 cm)条件下,采用未涂层石英毛细管(70 cm(有效分离长度57 cm)×75 μm)分离,以阿魏酸峰为参照,确定了17个共有指纹峰。对样品聚类分析后用其中9批生成对照CEFP(RCEFP),以其为标准,用系统指纹定量法鉴别出12批BZYXW质量为: 3批好,1批良好,3批中,1批一般,4批劣。三棱柱优化法为BGE选择提供了重要参考,建立的BZYXW-CEFP精密度好、重现性高,可用于BZYXW的质量控制。     

毛细管电泳指纹图谱应用于叶下珠药材中黄酮的检测

建立了叶下珠药材中黄酮的毛细管电泳指纹图谱。以硼砂和十二烷基磺酸钠(pH9.0)为背景电解质溶液,运行电压15kV,紫外检测波长245nm,流体静压力进样15s(高度12cm),对不同产地叶下珠药材进样检测。按电泳峰共有率fi≥70%为依据,确定10个不同产地叶下珠药材中黄酮的毛细管电泳指纹峰为8个,各产地叶下珠的毛细管电泳指纹图谱与标准毛细管电泳指纹图谱的相似度较好。在制备供试液后不同时间进样测定,各指纹峰的相对迁移时间的相对标准偏差小于5%,相对峰面积的相对标准偏差在3.0%～7.8%之间,结果表明样品在48h内稳定。     

Stacking and quantitative analysis of lovastatin in urine samples by the transient moving chemical reaction boundary method in capillary electrophoresis

A simple, sensitive, and useful concentration method for lovastatin (Lvt) in urine has been developed based on the transient moving chemical reaction boundary method (tMCRBM) in capillary electrophoresis. The MCRB is formed with acidic sample buffer (Gly-HCl) and alkaline running buffer (Gly-NaOH). The following optimal conditions were determined for stacking and separation: electrophoretic buffer of 100 mM Gly- NaOH (pH 11.52), sample buffer of 20 mM Gly-HCl (pH 4.93), fused-silica capillary of 76 cm × 75-μm i.d (67 cm from detector), sample injection at 14 mbar for 3 min. A 21- to 26-fold increase in peak height was achieved for detection of Lvt in urine under the optimal conditions compared with normal capillary zone electrophoresis. By combining the sample pretreatment procedure with the stacking method, the sensitivity of Lvt in urine was increased by 105- to 130-fold. The limits of detection (LOD) and quantification (LOQ) for Lvt in urine were decreased to 8.8 ng/mL and 29.2 ng/mL, respectively. The intra-day and inter-day precision values (expressed as RSD) were 2.23–3.61% and 4.03–5.05%, respectively. The recoveries of the analyte at three concentration levels changed from 82.65 to 100.49%.     

Stacking and determination of phenazine-1-carboxylic acid with low p<Emphasis Type="Italic">K</Emphasis><Subscript>a</Subscript> in soil via moving reaction boundaryformed by alkaline and double acidic buffers in capillary electrophoresis

As shown herein, a normal moving reaction boundary (MRB) formed by an alkaline buffer and a single acidic buffer had poor stacking to the new important plant growth promoter of phenazine-1-carboxylic acid (PCA) in soil due to the leak induced by its low pK _a. To stack the PCA with low pK _a efficiently, a novel stacking system of MRB was developed, which was formed by an alkaline buffer and double acidic buffers (viz., acidic sample and blank buffers). With the novel system, the PCA leaking into the blank buffer from the sample buffer could be well stacked by the prolonged MRB formed between the alkaline buffer and blank buffer. The relevant mechanism of stacking was discussed briefly. The stacking system, coupled with sample pretreatment, could achieve a 214-fold increase of PCA sensitivity under the optimal conditions (15 mM (pH 11.5) Gly-NaOH as the alkaline buffer, 15 mM (pH 3.0) Gly-HCl-acetonitrile (20%, v/v) as the acidic sample buffer, 15 mM (pH 3.0) Gly-HCl as the blank buffer, 3 min 13 mbar injection of double acidic buffers, benzoic acid as the internal standard, 75 μm i.d. × 53 cm (44 cm effective length) capillary, 25 kV and 248 nm). The limit of detection of PCA in soil was decreased to 17 ng/g, the intra-day and inter-day precision values (expressed as relative standard deviations) were 3.17–4.24% and 4.17–4.87%, respectively, and the recoveries of PCA at three concentration levels changed from 52.20% to 102.61%. The developed method could be used for the detection of PCA in soil at trace level.     

肌肽类生物活性肽的毛细管电泳在线富集技术

建立了毛细管区带电泳(CZE)在线富集3种肌肽类活性肽(肌肽、鹅肌肽和高肌肽)的两种简便有效的方法。一种是大体积进样反向压力排除基体富集（LVSRP）技术,即通过流体动力学进样,在不改变电源极性的条件下,利用反向压力排除样品基体,电堆积富集后进行CZE分离;另一种是大体积进样电渗流排除基体富集（LVSEP）技术,即通过流体动力学进样,于运行缓冲液中加入溴化十六烷基三甲基铵(CTAB)动态修饰毛细管表面,通过电渗流排除样品基体,改变电源极性后进行CZE分离。与常规CZE相比,LVSRP技术和LVSEP技术使检测灵敏度提高了40~60倍。对影响两种富集过程的一些因素进行了研究,在最优富集条件下考察本方法的线性范围为0.080~5.0 μmol/L。对3种生物活性肽的检测限(S/N=3)分别为LVSRP 41~58 nmol/L,LVSEP 35~43 nmol/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。     

Influence of buffer composition and sample pretreatment on efficiency separation for monitoring neuropeptides in plasma using capillary electrophoresis

More efficient and faster separation conditions for qualitative as well as quantitative analysis of neuropeptides in human plasma using capillary zone electrophoresis (CZE) have been developed. The analysis method for neuropeptides has been improved specifically to study thyroid hormone related neuropetides for the regulation of thyroid disease. In this study, we investigated the pretreatment methods, composition of the running buffer and rinsing procedures between runs in order to obtain more sensitive and faster separation of trace neuropeptides in plasma by CZE. The tested neuropeptides were somatostatin (SOMA), vasopressin (VP), neurotensin (NT), and thyrotropin-releasing hormone (TRH). Plasma samples were pretreated by deproteinization and solid-phase extraction method. The fraction of neuropeptides was reconstituted in 40% acetonitrile followed by ultrafiltration, and then analyzed by CZE. Resolution and sensitivity was improved using the separation buffer composition with 100 mM Tris-phosphate buffer (pH 2.0) while the sensitivity was further improved via a stacking method using the sample buffer of 40% acetonitrile. These sample pretreatment methods and buffer condition permit quantitative analysis on tested neuropeptides at the 20 ng/mL level. The rinsing procedures between runs using 90% ethanol dramatically shortened the rinsing time to 30 min.     

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。     

Trace analysis of zotepine and its active metabolite in plasma by capillary electrophoresis with solid phase extraction and head-column field-amplified sample stacking

A sensitive high-performance capillary zone electrophoresis (CZE) with head-column field-amplified sample stacking (FASS) in binary system has been developed for the simultaneous determination of zotepine and its active metabolite, norzotepine, in human plasma. The separation of zotepine and norzotepine was performed using a background electrolyte consisting of 50% ethylene glycol-borate buffer (20mM, pH 8.0) solution with 20% methanol as the running buffer and on-column detection at 200 nm. Under the optimal FASS-CZE condition, good separation with high efficiency and short analysis time is achieved. Several parameters affecting the separation and sensitivity of the drug were studied, including sample matrix, pH and concentrations of the borate buffer, ethylene glycol and methanol. Using clozapine as an internal standard, the linear ranges of the method for the determination of zotepine and norzotepine in human plasma were over 3-100 ng/mL; the detection limits of zotepine and norzotepine in plasma were 2 and 1 ng/mL, respectively. A sample pretreatment by means of solid-phase extraction (SPE) with subsequent quantitation by FASS-CZE was used. The application of the proposed method for determination of zotepine and norzotepine in plasma collected after oral administration of 125 mg zotepine in one schizophrenic patient was demonstrated.     

Quantitative study on selective stacking of zwitterions in large-volume sample matrix by moving reaction boundary in capillary electrophoresis

The paper advanced the theoretical procedures for quantitative design on selective stacking of zwitterions in full capillary sample matrix by a cathodic-direction moving reaction boundary (MRB) in capillary electrophoresis (CE) under control of electroosmotic flow (EOF). With the procedures, we conducted the theoretical computations on the selective stacking of two test analytes of L-histidine (His) and L-tryptophan (Trp) by the MRB created with 30 mM pH 3.0 formic acid-NaOH buffer and 2-80 mM sodium formate. The results revealed the following three predictions. At first, the MRB cannot stack His and Trp plugs if less than 12.5 mM sodium formate is used to form the MRB and prepare the sample matrix. Second, the MRB can stack His and/or Trp sample plugs completely if higher than 50 mM sodium formate is chosen to form the MRB. Third, the MRB can only focus His plug completely, but stack Trp plug partially if 20-50 mM sodium formate is used; this implied the complete MRB-induced selective stacking to His rather than Trp. All the three predictions were quantitatively proved by the experiments. With great dilution of sample matrix and control of EOF, controllable, simultaneous and MRB-induced selective stacking and separation of zwitterions were achieved. The theoretical results hold evident significances to the quantitative design of selective stacking conditions and the increase of detection sensitivity of zwitterions in CE. In addition, the control of EOF by cetyltrimethylammonium bromide (CTAB) can evidently improve the stacking efficiency to both His and Trp.     

Novel moving reaction boundary-induced stacking and separation of human hemoglobins in slab polyacrylamide gel electrophoresis

We developed a novel polyacrylamide gel electrophoresis (PAGE) method to stack and separate human hemoglobins (Hbs) based on the concept of moving reaction boundary (MRB). This differs from the classic isotachophoresis (ITP)-based stacking PAGE in the aspect of buffer composition, including the electrode buffer (pH 8.62 Tris–Gly), sample buffer (pH 6.78 Tris–Gly), and separation buffer (pH 8.52 Tris–Gly). In the MRB-PAGE system, a transient MRB was formed between alkaline electrode buffer and acidic sample buffer, being designed to move toward the anode. Hbs carried partial positive charges in the sample buffer due to its pH below pI values of Hbs, resulting in electromigrating to the cathode. Hbs would carry negative charges quickly when migrated into the alkaline electrode buffer and be transported to the anode until meeting the sample buffer again. Thus, Hbs were stacked within a MRB until the transient MRB reached the separation buffer and then separated by zone electrophoresis with molecular sieve effect of the gel. The experimental results demonstrated that there were three clear and sharp protein zones of Hbs (HbA_1c, HbA₀, and HbA₂) in MRB-PAGE, in contrast to only one protein zone (HbA₀) in ITP-PAGE for large-volume loading (≥15 μl), indicating high stacking efficiency, separation resolution, and good sensitivity of MRB-PAGE. In addition, MRB-PAGE was performed in a conventional slab PAGE device, requiring no special device. Thus, it could be widely used in separation and analysis of diluted protein in a standard laboratory.

Determination of preservatives by integrative coupling method of headspace liquid-phase microextraction and capillary zone electrophoresis

An integrative coupling method of headspace liquid-phase microextraction (HS-LPME) and capillary zone electrophoresis (CZE) was proposed in this paper. In the method, a separation capillary was used to create a microextraction droplet of the running buffer solution of CZE, hold the droplet at the capillary inlet, extract analytes of sample solutions in the headspace of a sample vial, inject concentrated analytes into the capillary and separate the analytes by CZE. The proposed method was applied to determine the preservatives of benzoic acid and sorbic acid in soy sauce and soft drink samples, in which the running buffer solution of 50 mmol/L tetraborate (pH 9.2) was directly used to form the acceptor droplet at the capillary inlet by pressure, and the preservatives in a 6-mL sample solution containing 0.25 g/mL NaCl were extracted at 90°C for 30 min in the headspace of a 14-mL sample vial. Then the concentrated preservatives were injected into the capillary at 10 cm height difference for 20 s and separated by CZE. The enrichment factors of benzoic acid and sorbic acid achieved 266 and 404, and the limits of detection (LODs) were 0.03 and 0.01 μg/mL (S/N=3), respectively. The recoveries were in the range of 88.7-105%. The integrative coupling method of HS-LPME and CZE was simple, convenient, reliable and suitable for concentrating volatile and semi-volatile organic acids and eliminating matrix interferences of real samples.