柱切换技术-高效液相色谱法快速检测大鼠血浆中的普萘洛尔对映体

建立了快速检测大鼠血浆中普萘洛尔对映体浓度的柱切换-高效液相色谱法。将自制限进填料柱作为预处理柱,通过直接进样方式,使普萘洛尔对映体在预处理柱上保留,同时除去血浆中的蛋白质等大分子;再通过柱切换技术,使普萘洛尔对映体在键合型纤维素-三(3,5-二甲基苯基氨基甲酸酯)(Chiralcel OD-RH)分析柱上得到手性拆分。通过条件优化,确定切换前预处理流动相为硼酸盐缓冲液(pH 8.5)-甲醇(95:5, v/v),流速为1.0 mL/min;切换后分析流动相为异丙醇-乙醇-0.2 mmol/L硼酸盐缓冲液(pH 8.5)(30:30:40, v/v/v),流速为0.8 mL/min;切换时间为3 min;柱温为25 ℃;检测波长为293 nm。普萘洛尔两对映体在25～500 mg/L的质量浓度范围内具有良好的线性关系(r=0.9995), 3个加标水平(50、100、250 mg/L)的平均回收率为97.89%～101.56%,日内和日间精密度均小于5%。该方法简便、快速、灵敏、准确,适于血浆样本中手性药物的药代动力学研究。     

柱切换-高效液相色谱法测定抗病毒口服液中非法添加利巴韦林

提出了由双泵单阀的驱动系统和双柱(预处理柱和分析柱)切换的分析系统所组成的色谱分析流程并应用于测定抗病毒口服液中非法添加物利巴韦林.样品离心后取上清液直接进样于C18预处理柱,水作为预处理流动相;用0.3 g·L-1磷酸二氢钠溶液(分析流动相)将保留在预处理柱上的药物冲入Kromasil C18分析柱(250 mm×4.6 mm,5μm)进行测定.方法集样品净化和色谱分析一次连续进行,测定条件下无干扰.检测波长205.6 am,药物的质量浓度在0.4～40.0 mg·L-1范围内呈线性(r=0.999 2),检出限(S/N=3)为0.08 mg·L-1,加标回收率分别为98.32%,98.45%,99.45%.     

柱切换高效液相色谱法测定人血浆中布洛芬对映体浓度

建立了柱切换高效液相色谱法测定人血浆中布洛芬对映体浓度的方法。以对溴苯甲酸为内标,样品经醋酸钠缓冲液酸化后,用V(正己烷)∶V(异丙醇)=95∶5萃取。以Chiralcel OJ-H柱(Daicel Chemicals,250mm×4.6mm,5μm)为分析柱,UltimateTM SiO柱(50mm×4.6mm,5μm)为预处理柱;流动相为V(正己烷)∶V(异丙醇)∶V(三氟醋酸)=96.5∶3.5∶0.1,流速为0.5mL/min;预处理流动相为V(正己烷)∶V(异丙醇)=99.5∶1,流速为1mL/min;柱切换时间为1.70~4.09min;紫外检测波长为230nm。布洛芬消旋体和S-( )-布洛芬标准曲线线性范围分别为0.21~20mg/L和0.10~10mg/L;日内RSD小于6.5%,日间RSD小于6.1%;方法回收率为93.3%~107.1%,萃取回收率为80.0%~86.6%。本法简便、准确,重现性好,可用于布洛芬对映体人体药代动力学研究。     

多维液相柱色谱

多维液相柱色谱分离分析复杂样品越来越受到重视。本文介绍了国内外多维液相柱色谱的近期发展,详细讨论了二维液相色谱的实现,其中包括固定相、流动相的选择、温度变量的作用以及两维间切换的实现,并对多维液相柱色谱的应用现状进行了总结。     

丙卡特罗在三种刷型手性固定相上的直接拆分

以正己烷-异丙醇二元混合溶剂体系为流动相,在Whelk-O1、 DNB-PG和DNB-Leucine 3种刷型手性固定相上将药物丙卡特罗直接拆分为(R,R/S)和(S,R/S)对映体,分离系数α值达1.4 ～1.8.考察了流动相组成及固定相分子结构对对映体分离效果的影响,同时对丙卡特罗与3种固定相的手性识别机理进行了探讨.结果表明,当流动相中异丙醇的体积分数(φB)为2% ～30%时,lnk′与lnφB之间呈现较好的线性关系.因此,在一定范围内可以根据所需色谱分离系数或保留时间估计流动相的组成.以后出峰对映体所表征的3种手性柱的色谱分离效能分别为:n(Whelk-O1)=10 816/m,n(DNB-PG)=4 532/m,n(DNB-Leucine)=12 844/m.DNB-PG柱柱效相对较低,谱峰展宽较大,且有轻微拖尾,需改善柱子装填和预处理技术以提高色谱分离柱效.     

高效液相色谱分析法测定色氨酸对映体

采用高效液相色谱法,以手性冠醚Crownpak CR( )为固定相、高氯酸溶液/甲醇混合溶液为流动相,成功地实现了色氨酸(Trp)对映体的色谱分离.考察了流动相中甲醇含量、流量和柱温等因素对分离效果的影响.研究表明,适当提高流动相中的甲醇含量、降低流动相流量、降低柱温可以有效地提高分离度.另一方面,提高流动相中的甲醇含量、提高流动相流量、升高柱温可以显著地缩短样品的保留时间.确定了一种最佳分析分离条件,即流动相为甲醇∶高氯酸溶液=15∶85(V/V),流动相流量0.8 mL/min,柱温20℃,波长220 nm,在此条件下进行色谱分离,样品的保留时间小于12 min,分离度达到2.06.该方法具有快速、高效、准确和精密度高等优点.     

柱切换-荧光检测反相高效液相色谱法测定血浆中特布他林浓度

采用柱切换技术 荧光检测反相高效液相色谱法测定血浆中特布他林 (TB)浓度。使用LunaC8( 2 )和KromasilC18为分析柱 ( 1 5 0mm× 4.6mm ,5 μm)和预处理柱 ( 2 5mm× 4.6mm ,5 μm) ,流动相分别为pH 3 0 ,0 .0 3 3mol/L磷酸盐缓冲液∶甲醇∶乙腈 ( 92∶7∶1 )和水∶甲醇∶乙腈 ( 97∶2∶1 ) ,流速均为 1 .0ml/L。血浆样品经乙腈沉淀蛋白后进样 ,切换时间为 3 .2～ 4.2min。荧光检测 ,λex为 2 80nm ,λem为 3 0 9nm。以沙丁胺醇作内标 ,按内标法定量。标准曲线线性范围为 0 .8～ 3 2 μg/L ;最低定量限为 0 .8μg/L;TB和内标的保留时间分别为 8.7和 9.3min;日内RSD小于 4% ,日间RSD小于 9% ,方法回收率在 93 %～ 1 1 2 %。     

采用自动前处理LC/MS进行血浆中药物的快速分析

药物研究的发展对高通量的样品处理分析提出了越来越高的要求,减少样品制备时间和分析时间是解决问题的关键。我们新近发展了一种具有在线稀释旁路和新的样品预处理柱的Shim-Pack MAYI-ODS自动柱切换HPLC和LC／MS系统,该系统无需样品前处理,可直接进样进行血浆、血清中的药物分析。本文利用自动样品前处理LC／MS系统,用ODS整体柱实现了血浆中药物的快速分析。包括样品预处理,整个分析仅需1．2min完成。     

离子色谱-柱切换技术同步测定饮料中的三氯蔗糖、葡萄糖、果糖和蔗糖

建立了一种离子色谱-柱切换-安培检测技术同步测定饮料中三氯蔗糖、葡萄糖、果糖和蔗糖的方法。以CarboPac PA10阴离子交换保护柱和分析柱进行分离,用水和250 mmol/L NaOH梯度淋洗,脉冲安培检测。弱保留糖类在25 mmol/L NaOH流动相淋洗下分离检测,通过柱切换将保护柱切换至分析柱后,同时切换至250 mmol/L NaOH淋洗,三氯蔗糖仅通过较短的保护柱分离,4种糖类能够得到同步检测。4种糖类在0.01~20 mg/L范围内有良好的线性关系和较低的检出限,重复性好,样品测定的回收率分别为90.38%~102.88%（三氯蔗糖）、95.56%~102.75%（葡萄糖）、101.66%~114.33%（果糖）和105.03%~106.49%（蔗糖）。该方法可广泛应用于食品中强保留物质的测定。     

柱切换直接进样高效液相色谱法测定蜂蜜中3种抗生素的残留量

建立了柱切换反相高效液相色谱法直接进样分离、测定蜂蜜中3种四环素族抗生素(土霉素OTC、四环素TC、金霉素CTC)残留量的分析方法。方法包括：用缓冲溶液溶解样品、直接进样、二次蒸馏水作流动相在C18预柱上在线富集和净化，然后用柱切换阀将预柱与一个C18分析柱接通，草酸溶液-乙腈-甲醇作流动相、紫外检测器在350nm处检测。各组分回收率均大于85％；相对标准偏差小于10％；标准曲线的相关系数在0．9983～0．9991之间；最低检出浓度(≤0．02mg／kg)，满足欧盟和日本等国要求(0．05mg／kg)。     

Establishing a selectivity survey as part of the method development activity for an isocratic reversed-phase liquid chromatographic method

Often high-performance liquid chromatography method development is done by choosing a single C18 column and optimizing only the mobile phase composition. In this paper, it is demonstrated how to evaluate and optimize the best combination of the different stationary phase chemistries and mobile phases for a limited method development activity. By using column and mobile phase switching, it is possible to automate most of the activity in a nine-step process. Columns are chosen to represent the range of selectivity currently available. Interestingly, although the most popular column is the C18 phase, it is not the best column for the optimized methods in the cases studied.     

Fast Separation Method Development for Supercritical Fluid Chromatography Using an Autoblending Protocol

Supercritical fluid chromatography (SFC) is a powerful separation technique particularly in the area of enantioseparations. With rapid analysis speed, wide polarity compatibility, higher column efficiency and lower cost of the mobile phase, SFC is regarded as a better choice than high-performance liquid chromatography for drug discovery. In the development of separation method, the choice of modifier and/or additive is the key point of optimum separation. However, such screening of SFC is typically time-consuming. In this study, an autoblending protocol was introduced to speed up the modifier and/or additive screening process, which was performed on a separate programmable gradient proportioning system. The protocol prepares mobile phases on the fly to speed up the screening of modifiers and/or additives and reduces the waste of solutions. Furthermore, by switching mobile phase in the same run, separation of different types of compounds could also be achieved. This system was successfully applied to screen modifier–additive combinations of three alkaloids and three polyphenols by switching to two mobile phase conditions, as well as by a ternary additive mobile phase on an SFC system. The proposed protocol allows fast separation method development of SFC, which was proved to be rapid, simple, and reproducible.     

Fast Separation Method Development for Supercritical Fluid Chromatography Using an Autoblending Protocol

Supercritical fluid chromatography (SFC) is a powerful separation technique particularly in the area of enantioseparations. With rapid analysis speed, wide polarity compatibility, higher column efficiency and lower cost of the mobile phase, SFC is regarded as a better choice than high-performance liquid chromatography for drug discovery. In the development of separation method, the choice of modifier and/or additive is the key point of optimum separation. However, such screening of SFC is typically time-consuming. In this study, an autoblending protocol was introduced to speed up the modifier and/or additive screening process, which was performed on a separate programmable gradient proportioning system. The protocol prepares mobile phases on the fly to speed up the screening of modifiers and/or additives and reduces the waste of solutions. Furthermore, by switching mobile phase in the same run, separation of different types of compounds could also be achieved. This system was successfully applied to screen modifier–additive combinations of three alkaloids and three polyphenols by switching to two mobile phase conditions, as well as by a ternary additive mobile phase on an SFC system. The proposed protocol allows fast separation method development of SFC, which was proved to be rapid, simple, and reproducible.

     

Increased Flexibility in Multicolumn Chromatography (MC[sbnd]HPLC) via On-line Effluent Mixing Technique

Abstract

In continuation of our work dealing with multicolumn HPLC (MC[sbnd]HPLC) we describe in this paper an on-line on-column fraction trapping technique based on effluent mixing.

To a normal two-column switching set-up (in this case with two RP columns) an additional high-pressure pump gets inserted into the connection line between column A and column B via a low dead volume mixing tee. The in-line respectively off-line switching of pump B and the mobile phase B is time controlled by using a high pressure switching valve. With this set-up it is possible to mix on-line an effluent fraction from column A and transferred onto column B with a highly polar and pH-controlled (e.g. aqueous buffer) new effluent, to reduce or adjust significantly the overall elution strength of this mixed transferred solvent. Thus, several chromatographically effective possibilities can be created in a simple manner, which are for example: (a) pronounced peak compression respectively on-column concentration on column B; (b) due to low elution strength and/or pH adjustment during the trapping period on column B, increments to the overall selectivity of the column switching set-up can be added creating multidimensionality via mobile phase switching; (c) combining the heart cut with the effluent mixing technique enables analysis of trace peaks eluted on the back flank of an overloaded main peak.     

Separation of phenolic compounds and corresponding glucuronides by coupled-column micellar reversed-phase liquid chromatography

Summary An isocratic HPLC technique for separation of phenolic compounds and corresponding glucuronides in urine is developed. Sample pre-treatment, often a tedious and rate-limiting factor, was eliminated by use of a coupled column system. Spiked urine samples were injected directly into a C₄ precolumn and a selected fraction was transferred on-line from the precolumn to a silanized C₁₈ analytical column in the backflush mode. Analyte peak enrichment was attained by employing mobile phases of different elution strengths. The weaker mobile phase (7% v/v acetonitrile) was used to strongly retain the analytes on the precolumn while most of the polar endogenous compounds were washed to waste. Elution and transfer of the trapped analytes from the precolumn to the analytical column was achieved by introducing a stronger mobile phase (20% v/v acetonitrile) with the aid of a switching valve. The use of cetyltrimethylammonium bromide as counter ion and micellar agent in the mobile phase involved a high selectivity for the analytes relative to the urine matrix components and allowed simultaneous analysis of the glucuronides and parent compounds without the need of gradient elution. The system demonstrated a good repeatability on spiked urine samples. Who passed away July 21, 1996     

手性微柱高效液相色谱用于对映体的分离

报道了实验室自制的手性微柱高效液相色谱系统和纤维素类手性填料的制备方法, 以及用于对映体分离的应用研究. 研究了手性微柱的装填技术并考察了影响填料性能的关键因素. 优化了流动相的组成和流速对对映体拆分的影响. 成功地分离了5种对映体. 结果表明, 该系统操作简便、分离度高, 而且流动相消耗低, 分析速度快. 该系统可以用于实验室手性分离分析.     

反相毛细管电色谱中无盐体系的优势及分离研究

本文将电中性溶质在缓冲盐体系和无盐体系下的电渗流、分离选择性等进行了对比,从理论和实验两方面讨论了电中性溶质在无盐体系下的分离,提出了采用无盐流动相既可以增加电渗流也可以减小焦耳热的优势。反相毛细管电色谱的实验结果也充分证明了这一点。     

A Reverse Phase HPLC Assay for the Determination of Calcium Pantothenate Utilizing Column Switching

Abstract

A reverse phase HPLC assay utilizing column switching has been developed and validated for the determination of calcium pantothenate (CP) in several multivitamin tablet formulations. The reverse phase system utilizes a DuPont Zorbax C-8 analytical column, an automatically switched and backflushed Brownlee RP-18 guard column for the elimination of a highly retained excipient peak, 88:12 0.25M phosphate buffer:MeOH mobile phase, and 214 nm detection. Sample preparation and the switched column chromatography cycle each require approximately 15 minutes. A spiked recovery study showed linearity over the 50–150% of theory concentration range. Average recovery was 99.7%. Assay precision studies yielded sample RSD's ranging from 0.8 to 2.3%. Results obtained by this method are comparable to those obtained by the USP method.     

Flow inconsistency: The evil twin of column switching—Hardware aspects

Solvent flow, generated by HPLC pumps is consistent and accurate. This statement, while true for single column (one dimensional) liquid chromatography applications, may not apply to column switching applications. Connection of pumps and/or columns to one flow path may cause substantial pressure changes. Immediate post valve switch pressure differences between pumps can cause backflow where the mobile phase stored at higher pressure will temporary flow into the lower pressure area. A more common side effect of column switching is flow inconsistency during pump pressurization. For the duration of pump pressurization, liquid flow through the column will be smaller than expected since the HPLC column acts like a flow restrictor.