Influence of sample application mode on performance of pressurized planar electrochromatography in completely closed system

Three modes of sample application on the chromatographic plate are applied at present investigations of pressurized planar electrochromatography (PPEC) systems taking into special attention their influence on performance of the separating system. These modes are as follows: application of the sample solution directly on the chromatographic plate with microsyringe, deposition of sample solution on scrap of adsorbent layer followed by location oft this scrap on the chromatographic plate, application of the sample solution with commercially available aerosol applicator. These modes were combined with prewetting procedures of the chromatographic plates which lead to an accomplishment of equilibration of the stationary phase-mobile phase system. The plots of plate height versus linear flow rate of the mobile phase are presented for PPEC systems for the first time. The best separation performance has been obtained in PPEC system when prewetting of the chromatographic plate followed the sample application with commercially available aerosol applicator. The higher repeatability of migration distance of the solute bands has been obtained in PPEC experiments when the sample application was followed by prewetting the chromatographic plate in comparison to the experiments when these operations were performed in reversed order.     

A Modified Device for Pressurized Planar Electrochromatography and Preliminary Results with On-Line Sample Application

Pressurized planar electrochromatography (PPEC) is a separating technique in which an electric field is applied to force the mobile phase movement through a porous media (electroosmotic effect). High separation efficiency, fast separations and changes in separation selectivity in comparison to liquid chromatography, especially thin layer chromatography (planar chromatography, TLC), are features of this technique. Constructional methodological challenges to PPEC are obstacles to its development and application in laboratory practice. In this article, an attempt to overcome the challenges related to device construction and sample application/injection is described. The introduced device enables both prewetting of the adsorbent layer and electrochromatogram development with a single PPEC device. It also enables simultaneous application/injection of six samples on a chromatographic plate in a stream of the mobile phase (on-line application/injection). In addition, the PPEC chamber was equipped with a thermostat. The device is characterized by an impressive throughput in comparison to the other planar technique, TLC/HPTLC. Although the developed device still needs improvement, it is, in our opinion, a considerable step toward possible automation of this planar separation technique.     

Pressurized planar electrochromatography,high-performance thin-layer chromatography and high-performance liquid chromatography—Comparison of performance

Kinetic performance, measured by plate height, of High-Performance Thin-Layer Chromatography (HPTLC), High-Performance Liquid Chromatography (HPLC) and Pressurized Planar Electrochromatography (PPEC) was compared for the systems with adsorbent of the HPTLC RP18W plate from Merck as the stationary phase and the mobile phase composed of acetonitrile and buffer solution. The HPLC column was packed with the adsorbent, which was scrapped from the chromatographic plate mentioned. An additional HPLC column was also packed with adsorbent of 5 μm particle diameter, C18 type silica based (LiChrosorb RP-18 from Merck). The dependence of plate height of both HPLC and PPEC separating systems on flow velocity of the mobile phase and on migration distance of the mobile phase in TLC system was presented applying test solute (prednisolone succinate). The highest performance, amongst systems investigated, was obtained for the PPEC system. The separation efficiency of the systems investigated in the paper was additionally confirmed by the separation of test component mixture composed of six hormones.     

Separation of four mixtures of pesticides by pressurized planar electrochromatography (PPEC)

Examples of separations of four mixtures of pesticides by pressurized planar electrochromatography (PPEC) under different operating conditions are presented. The samples were separated on a prewetted RP-18W chromatographic plate in a system with acetonitrile-buffer as the mobile phase. A potential of 2.3 kV was applied to a 10 cm long plate to create the electric field. Reproducible retention of pesticides was obtained during PPEC in the closed system when the sorbent layer of the plate was prewetted and equilibrated with the mobile phase. The reported separations of pesticides by PPEC are over 10 times faster than the corresponding separations by TLC.     

Correlation of Migration Distance of Peptides in High-Performance Thin-Layer Chromatography and Pressurized Planar Electrochromatography Systems

In a series of our previous papers we have investigated the influence of various variables on retention/migration of peptides in various high-performance thin-layer chromatography (HPTLC) and pressurized planar electrochromatography (PPEC) systems. Here we present a correlation of the selectivity of peptide separation in similar, as well as in various HPTLC and PPEC systems investigated before. Our results show that the selectivity in similar HPTLC and PPEC systems is quite different. This results from the share of electrophoresis in separation of solutes by PPEC. The results suggest that combination of HPTLC and PPEC, with properly selected separation conditions (the same, or even better—different for each technique), may be used for efficient two-dimensional separation of peptides. The best separation can be obtained if PPEC is carried out in two opposite directions (toward the cathode and the anode) simultaneously.     

Improved separation and quantitative determination of hydrocarbon types in gas oil by normal phase high‐performance TLC with UV and fluorescence scanning densitometry

Improved methods for separation and quantitative determination of hydrocarbon types from gas oil have been developed, which were based on high‐performance thin‐layer chromatography with ultraviolet and fluorescence scanning densitometry using horizontal elution. One of the methods allows the separation, detection, and determination of alkanes and naphthenes to be carried out, using berberine‐impregnated silica gel HPTLC plates, elution with n‐hexane, and berberine‐induced fluorescence detection at 365 nm. Another developed method allows total aromatics to be determined using silica gel HPTLC plates by elution with n‐hexane and acetone, and UV detection. In turn, PACs over three aromatic rings can be determined on either silica gel or caffeine‐impregnated silica gel HPTLC plates, elution with n‐hexane, and selective detection using native fluorescence at 365 nm. Concentrations lower than 5 wt% can be determined using this technique. In addition, a technique for an efficient, baseline‐resolved separation of a gas oil according to the number of aromatics rings (mono + di‐, tri‐, and polyaromatic compounds with more than three rings) is presented here. This technique involves a multistep elution on a mixed (silica gel and caffeine‐impregnated silica gel HPTLC plate) using a counter‐elution device, and UV detection.     

Densitometry and indirect normal‐phase HPTLC–ESI–MS for separation and quantitation of drugs and their glucuronide metabolites from plasma

The present work describes novel methods using densitometry and indirect or off‐line high performance thin‐layer chromatography–mass spectrometry (HPTLC–MS) for the simultaneous detection and quantification of asenapine, propranolol and telmisartan and their phase II glucuronide metabolites. After chromatographic separation of the drugs and their metabolites the analytes were scraped, extracted in methanol and concentrated prior to mass spectrometric analysis. Different combinations of toluene and methanol–ethanol–n‐butanol–iso‐propanol were tested for analyte separation and the best results were obtained using toluene–methanol–ammonia (6.9:3.0:0.1, v/v/v) as the elution solvent. All of the drug–metabolite pairs were separated with a homologous retardation factor difference of ≥22. The conventional densitometric approach was also studied and the method performances were compared. Both of the approaches were validated following the International Conference on Harmonization guidelines, and applied to spiked human plasma samples. The major advantage of the TLC–MS approach is that it can provide much lower limits of detection (1.98–5.83 pg/band) and limit of quantitation (5.97–17.63 pg/band) with good precision (?3.0% coefficient of variation) compared with TLC–densitometry. The proposed indirect HPTLC–MS method is simple yet effective and has tremendous potential in the separation and quantitation of drugs and their metabolites from biological samples, especially for clinical studies.     

Preparative separation of anti‐oxidative constituents from Rubia cordifolia by column‐switching counter‐current chromatography

An effective column‐switching counter‐current chromatography (CCC) protocol combining stepwise elution mode was successfully developed for simultaneous and preparative separation of anti‐oxidative components from ethyl acetate extract of traditional Chinese herbal medicine Rubia cordifolia. The column‐switching CCC system was interfaced by a commercial low‐pressure six‐port switching valve equipped with a sample loop, allowing large volume introduction from the first dimension (1^st‐D) to the second dimension (2^nd‐D). Moreover, to extend the polarity window, three biphasic liquid systems composed of n‐hexane/ethyl acetate/methanol/water (1:2:1:2, 2:3:2:3, 5:6:5:6 v/v) were employed using stepwise elution mode in the 1^st‐D. By valve switching technique the whole interested region of 1^st‐D could be introduced to second dimension for further separation with the solvent system 5:5:4:6 v/v. Using the present column‐switching CCC protocol, 500 mg of crude R. cordifolia extract were separated, producing milligram‐amounts of four anti‐oxidative components over 90% pure. Structures of purified compounds were identified by ¹H and ¹³C NMR.     

Automated high‐speed CE system for multiple samples

A high‐speed CE system for multiple samples was developed based on a short capillary and an automated sample introduction device consisting of a commercial multi‐well plate and an x‐y‐z translation stage. The spontaneous injection method was used to achieve picoliter‐scale sample injection from different sample wells. Under the optimized conditions, a 40 μm‐long sample plug (corresponding to 78‐pL plug volume) was obtained in a 50 μm id capillary, which ensured both the high separation speed and high separation efficiency. The performance of the system was demonstrated in the separation of FITC‐labeled amino acids with LIF detection. Five FITC‐labeled amino acids including arginine, phenylalanine, glycine, glutamic acid, and asparagine were separated within 15 s with an effective separation length of 1.5 cm. The separation efficiency ranged from 7.96 × 10⁵/m to 1.12 × 10⁶ /m (corresponding to 1.26–0.89 μm plate heights). The repeatability of the peak heights calibrated with an inner standard for different sample wells was 2.4 and 2.7% (n = 20) for arginine and phenylalanine, respectively. The present system was also applied in consecutive separations of 20 different samples of FITC‐labeled amino acids with a whole separation time of less than 6 min.     

Simultaneous densitometric determination of shikonin,acetylshikonin, and β‐acetoxyisovaleryl‐shikonin in ultrasonic‐assisted extracts of four Arnebia species using reversed‐phase thin layer chromatography

A simple, precise, and rapid high‐performance thin‐layer chromatographic (HPTLC) method for the simultaneous quantification of pharmacologically important naphthoquinone shikonin ( 1 ) together with its derivatives acetylshikonin ( 2 ), and β‐acetoxyisovalerylshikonin ( 3 ) in four species of genus Arnebia (A. euchroma, A. guttata, A. benthamii, and A. hispidissima) from the Indian subcontinent has been developed. In addition, the effect of solvents with varying polarity (hexane, chloroform, ethyl acetate, and methanol) for the extraction of these compounds was studied. HPTLC was performed on precoated RP‐18 F_254S TLC plates. For achieving good separation, mobile phase consisting of ACN/methanol/5% formic acid in water (40:02:08 v/v/v) was used. The densitometric determination of shikonin derivatives was carried out at 520 nm in reflection/absorption mode. The method was validated in terms of linearity, accuracy, precision, robustness, and specificity. The calibration curves were linear in the range of 100–600 ng for shikonin and acetylshikonin, and 100–1800 ng for β‐acetoxyisovalerylshikonin. Lower LOD obtained for compounds 1 – 3 were 18, 15, and 12 ng, respectively, while the LOQ obtained were 60, 45, and 40 ng, respectively.     

Two‐dimensional HPLC analysis of oligostyrenes: Comprehensive and online heart‐cutting techniques

2‐D HPLC incorporating two reversed phase (RP) environments was employed for the isolation of oligomers and their diastereomers of low molecular weight oligostyrenes. The operation of a comprehensive method of analysis was compared to a heart‐cutting approach. The comprehensive approach employed a high resolution diastereomer separation in the first dimension and a low peak capacity C18, high speed separation according to molecular weight. Because of solvent incompatibility between the dimensions in the comprehensive method, successful separation of the diastereomers of the oligomers was not possible. The heart‐cutting approach used a C18 monolith in the first dimension, which was selective only for molecular weight. Entire molecular weight fractions were then transported to the second dimension in an online heart‐cutting process for the separation of diastereomers. The heart‐cutting process was more successful in that 228 components of the 511 within the sample were recognized. This series of separations was undertaken in less than 6 h.     

Heart‐cutting 2D‐CE with on‐line preconcentration for the chiral analysis of native amino acids

The use of transient moving chemical reaction boundary (tMCRB) was investigated for the on‐line preconcentration of native amino acids in heart‐cutting 2D‐CE with multiple detection points using contactless conductivity detection. The tMCRB focusing was obtained by using ammonium formate (pH 8.56) as sample matrix and acetic acid (pH 2.3) as a BGE in the first dimension of the heart‐cutting 2D‐CE. Different experimental parameters such as the injected volume and the concentration in ammonium formate were optimized for improving the sensitivity of detection. A stacked fraction from the first dimension was selected, isolated in the capillary, and then separated in the second dimension in the presence of a chiral selector ((+)‐(18‐crown‐6)‐2,3,11,12‐tetracarboxylic acid). This on‐line tMCRB preconcentration coupled with heart‐cutting 2D‐CE was applied with success to the chiral separation of D ,L ‐phenylalanine, and D ,L ‐threonine in a mixture of 22 native amino acids. The sample mixture was diluted in 0.8 M of ammonium formate, and injected at a concentration of 2.5 μM for each enantiomer with a volume corresponding to 10% of the total capillary volume. An LOD (S/N=3) of 2 μM was determined for L ‐threonine.     

Purification of flavonoids from licorice using an off‐line preparative two‐dimensional normal‐phase liquid chromatography/reversed‐phase liquid chromatography method

An orthogonal (71.9%) off‐line preparative two‐dimensional normal‐phase liquid chromatography/reversed‐phase liquid chromatography method coupled with effective sample pretreatment was developed for separation and purification of flavonoids from licorice. Most of the nonflavonoids were firstly removed using a self‐made Click TE‐Cys (60 μm) solid‐phase extraction. In the first dimension, an industrial grade preparative chromatography was employed to purify the crude flavonoids. Click TE‐Cys (10 μm) was selected as the stationary phase that provided an excellent separation with high reproducibility. Ethyl acetate/ethanol was selected as the mobile phase owing to their excellent solubility for flavonoids. Flavonoids co‐eluted in the first dimension were selected for further purification using reversed‐phase liquid chromatography. Multiple compounds could be isolated from one normal‐phase fraction and some compounds with bad resolution in one‐dimensional liquid chromatography could be prepared in this two‐dimensional system owing to the orthogonal separation. Moreover, this two‐dimensional liquid chromatography method was beneficial for the preparation of relatively trace flavonoid compounds, which were enriched in the first dimension and further purified in the second dimension. Totally, 24 flavonoid compounds with high purity were obtained. The results demonstrated that the off‐line two‐dimensional liquid chromatography method was effective for the preparative separation and purification of flavonoids from licorice.     

Reversed‐Phase High‐Performance Liquid Chromatographic Separation and Determination of 4‐Amino‐azobenzene‐4′,5‐disulfonic Acid and Related Products in Industrial Wastewater Effluents

A simple and rapid reversed‐phase high‐performance liquid chromatographic method for the separation and determination of 4‐amino‐azobenzene‐4′,5‐disulfonic acid (AABDS) and its process‐related impurities was developed. The separation was achieved on a μ‐Bondapak C₁₈ column using 0.15 M ammonium sulfate‐acetonitrile (55:45) (v/v) as eluent. A UV‐visible spectrophotometric detector fixed at 386 nm was used both for detection and quantitation. The method was used not only for quality assurance but also for process development and wastewater management of AABDS.     

Determination of Free Fatty Acids by Diphasic-Two Dimensional TLC-Fluorescence Spectrodensitometry

Abstract

A sensitive method for the determination of fatty acids is presented. Free fatty acids (20pg-lμg), were first covalently reacted in a displacement reaction with a 70 μM solution of the fluorescent probe, 4-bromomethy 1–6, 7-dimethoxy-coumarin (Br- Mdmc) and the fluorescence-labelled fatty acid esters were separated in a diphasic-two dimensional high performance thin layer chromatographic system (diphasic-2D-TLC). This system consisted of a reversed phase C18 layer (2 × 10 cm) interfaced with a AgNO3-modified silica gel layer (10 × 10 cm). Aliquots of the reeaction mixture were streaked onto the C18 layer, and the plates developed in the first dimension using acetonitrile-acetone-methanol-water (60:20:10:10, v/v/v/v) (solvent 1) as the mobile phase. Development in this dimension gave separation based on the number of carbons. Following the first development, the plates were dried and the silica gel layer impregnated with a saturated solution of AgNO3 in methanol. The plates were then predeveloped in the second dimension in chloroform-ethyl acctate-acetonitrile (90:8:2, v/v/v) (solvent 2) to the plate interphase, and developed in solvent 2 in the second dimension. Development in the AgNO3-modified silica gel, allowed separation based on the number of double bonds. The fluorescent bands were scanned with a Shimadzu CS-9000 spectrodensitometer in the fluorescent mode, using 352 nm as the excitation wavelength and a cut-off filter at 400 nm. Baseline resolution was obtained for all 15 fatty acids tested. The lower linear detector response extended to 0.13 pmol. This method provids a sensitive means of analysis of fatty acids present in biological systems.     

Evaluation of new silica‐based humic acid stationary phase for the separation of tocopherols in cold‐pressed oils by normal‐phase high‐performance liquid chromatography

A new humic acid stationary phase was prepared by immobilizing humic acid onto aminopropyl silica via an amide linkage formation and used, for the first time, for the separation and quantification of the tocopherol compounds in cold‐pressed oil samples under normal‐phase high‐performance liquid chromatography conditions. Parameters affecting the chromatographic separation such as mobile phase composition and flow rate were optimized. By evaluating the calculations of capacity factor, asymmetry factor, resolution, selectivity factor, and theoretical plate number, the best separation was obtained with isocratic elution of n‐hexane and isopropyl alcohol (99:1% v/v) at a flow rate of 1.0 mL/min. The effluent was monitored by a fluorescence detector set at excitation and emission wavelengths 295 and 330 nm, respectively. All compounds were separated in 20 min. The method was validated according to international guidelines and found to be linear in a wide concentration range, also the mean recovery of the compounds ranged from 97.9 to 99.2%, with a CV less than 2.7% in all cases. The results showed that the developed stationary phase is suitable for the separation and quantification of the tocopherol compounds in real oil samples.     

On‐plate enzyme and inhibition assay of glucose‐6‐phosphate dehydrogenase using thin‐layer chromatography

We performed on‐plate enzyme and inhibition assays of glucose 6‐phosphate dehydrogenase using thin‐layer chromatography. The assays were accomplished based on different retardation factors of the substrates, enzyme, and products. All the necessary steps were integrated on‐plate in one developing process, including substrate/enzyme mixing, reaction starting, and quenching as well as product separation. In order to quantitatively measure the enzyme reaction, the developed plate was then densitometrically evaluated to determine the peak area of the product. Rapid and high‐throughput assays were achieved by loading different substrate spots and/or enzyme (and inhibition) spots in different tracks on the plate. The on‐plate enzyme assay could be finished in a developing time of only 4 min, with good track‐to‐track and plate‐to‐plate repeatability. Moreover, we determined the K_m values of the enzyme reaction and K_i values of the inhibition (Pb²⁺ Cd²⁺ and Cu²⁺ as inhibitors), as well as the corresponding kinetics using the on‐plate assay. Taken together, our method expanded the application of thin‐layer chromatography in enzyme assays, and it could be potentially used in research fields for rapid and quantitative measurement of enzyme activity and inhibition.     

A 2‐D‐HPLC‐CE platform coupled to ESI‐TOF‐MS to characterize the phenolic fraction in olive oil

A 2‐D‐HPLC/CE method was developed to separate and characterize more in depth the phenolic fraction of olive oil samples. The method involves the use of semi‐preparative HPLC (C18 column 250×10 mm, 5 μm) as a first dimension of separation to isolate phenolic fractions from commercial extra‐virgin olive oils and CE coupled to TOF‐MS (CE‐TOF‐MS) as a second dimension, to analyze the composition of the isolated fractions. Using this method, a large number of compounds were tentatively identified, some of them by first time, based on the information concerning high mass accuracy and the isotopic pattern provided by TOF‐MS analyzer together with the chemical knowledge and the behavior of the compounds in HPLC and CE. From these results it can be concluded that 2‐D‐HPLC‐CE‐MS provides enough resolving power to separate hundreds of compounds from highly complex samples, such as olive oil. Furthermore, in this paper, the isolated phenolic fractions have been used for two specific applications: quantification of some components of extra‐virgin olive oil samples in terms of pure fractions, and in vitro studies of its anti‐carcinogenic capacity.     

Purification of alkaloids from Corydalis yanhusuo W. T. Wang using preparative 2‐D HPLC

Two‐dimensional preparative multi‐channel parallel high performance liquid chromatography was successfully applied for the first time to isolate and purify alkaloids from Corydalis yanhusuo. The experiments were performed in off‐line mode using the same preparative chromatographic column with pH 3.5 in the first and pH 10.0 in the second separation dimension. In the preparative process, UV‐triggered fraction collection was used in the first dimension while UV and MS‐triggered collection were used in the second dimension for reasons of sensitivity and complementarity. Two pure compounds and nine fractions were obtained in the first dimension. Then two representative fractions were further purified in the second dimension and six pure compounds were obtained. The results demonstrated that this procedure is an effective approach for the preparative isolation and purification of alkaloids from Corydalis yanhusuo. Based on the different pH values of the mobile phase in this method, it is also suitable for the preparative isolation and purification of other compounds from TCMs which are sensitive to the pH of the solutions. Moreover, this method will be a promising tool for the purification of low content compounds from natural products.     

Online high‐pH reversed‐phase liquid chromatography × low‐pH reversed‐phase liquid chromatography tandem electrospray ionization mass spectrometry combined with pulse elution gradient in the first dimension for the analysis of alkaloids in Macleaya cordata (willd.) R. Br

An online high‐pH reversed‐phase liquid chromatography× low‐pH reversed‐phase liquid chromatography tandem electrospray ionization mass spectrometry combined with pulse elution gradient in the first dimension was constructed to separate and identify alkaloids from Macleaya cordata (willd.) R. Br. The modulation was performed by using a dual second dimensional columns interface combined with a make‐up dilution pump, which is responsible for dilution and neutralization of the first dimensional effluent, and the dual second dimensional columns integrated the trapping and the separation function to reduce the second dimension system dead volume. Taking advantage of the dissociable characteristics of alkaloids, mobile phases with different pH values were applied in the first dimension (pH 9.0) and the second dimension (pH 2.6) to improve the orthogonality of two‐dimension separation. Besides, the pulse elution gradient in first dimension and second dimensional gradient were carefully optimized and much better separation was achieved compared to the separation with the traditional two‐dimensional liquid chromatography approach. Finally, mass measurement was performed for alkaloids in M. cordata (willd.) R. Br. by coupling proposed two‐dimensional liquid chromatography system with triple quadrupole mass spectrometry, and 39 alkaloids were successfully identified by comparing the obtained result with the former reported results.