Analysis of heterogeneous fluorescence decays. Distribution of pyrene derivatives in an octadecylsilane layer in capillary electrochromatography

The distribution of solute molecules in the stationary phase in capillary electrochromatography (CEC) has been investigated with time-resolved fluorescence in the frequency domain. The analysis of fluorescence decay poses a challenging problem for the complex decay kinetics of heterogeneous systems such as the C18 stationary phase. The nonlinear least-squares (NLLS) method selects the decay model by minimizing the chi2 value. The chi2 criterion, in conjunction with the requirement that the residues should be randomly distributed around zero, frequently leads to a feasible set of multiple decay models that can all fit the data satisfactorily. The maximum entropy method (MEM) further chooses a unique model from the group of feasible ones by maximizing the Shannon-Jaynes entropy. The unique model, however, is not necessarily the most probable one. In this paper, the best model for the fluorescence decays of solute molecules is selected with NLLS using the chi2 statistics, the stability of the fit, and the consistency within replicate experiments. In addition, the recovered lifetime parameters of the true model should display the same trend as the fluorescence decay profiles when an experimental condition is varied. Using these criteria, a Gaussian distribution of fluorescence lifetimes satisfactorily fits the data under all experimental conditions. An additional minor component with a discrete lifetime is attributed to the systematic errors in the measurements. The distribution is a manifestation of an ensemble of heterogeneous microenvironments in the stationary phase of CEC. MEM is not suitable for the modeling of CEC data because of its inaccuracy in recovering broad fluorescence lifetime distributions and its lack of consistency in the replicate measurements in the studies of high-voltage effects.     

Imaging solute distribution in capillary electrochromatography with laser scanning confocal microscopy

A method for the direct observation of solute molecules interacting with a C18 stationary phase under real separation conditions in capillary electrochromatography (CEC) is investigated. The experiments were performed in a capillary electrochromatographic mode; however, the method and findings are useful both in CEC and revered-phase liquid chromatography. The distribution of solute molecules in the packed capillary is directly imaged with laser scanning confocal fluorescence microscopy. Conventional imaging techniques produce images where the C18 silica beads cannot be distinctively identified as a result of the deep depth of field. The optical sectioning capability of confocal imaging overcomes this problem to afford clearly defined images of the stationary-phase packing and the surrounding mobile phase. Fluorescein molecules are preferentially distributed in the mobile phase under reversed-phase chromatographic conditions. Nile Red and rhodamine 6G molecules prefer the environments of the porous C18 beads. Intensity distributions over time for areas within the stationary-phase beads differ from distributions of areas outside the beads in the mobile phase. Images taken at different depths into the capillary probe the internal structure of the C18 beads. While the internal structures of most beads are porous, confocal images show a small fraction (2%) of the silica beads have porous shells and nonporous cores. The capability of imaging the stationary phase distinctively from the mobile phase opens the possibilities of studying the quality of stationary phase, the structure of the column packing, and the mechanisms of separation.     

Incorporation of single-wall carbon nanotubes into an organic polymer monolithic stationary phase for mu-HPLC and capillary electrochromatography

Single-wall carbon nanotubes (SWNT) were incorporated into an organic polymer monolith containing vinylbenzyl chloride (VBC) and ethylene dimethacrylate (EDMA) to form a novel monolithic stationary phase for high-performance liquid chromatography (HPLC) and capillary electrochromatography (CEC). The retention behavior of neutral compounds on this poly(VBC-EDMA-SWNT) monolith was examined by separating a mixture of small organic molecules using micro-HPLC. The result indicated that incorporation of SWNT enhanced chromatographic retention of small neutral molecules in reversed-phase HPLC presumably because of their strongly hydrophobic characteristics. The stationary phase was formed inside a fused-silica capillary whose lumen was coated with covalently bound polyethyleneimine (PEI). The annular electroosmotic flow (EOF) generated by the PEI coating allowed peptide separation by CEC in the counterdirectional mode. Comparison of peptide separations on poly(VBC-EDMA-SWNT) and on poly(VBC-EDMA) with annular EOF generation revealed that the incorporation of SWNT into the monolithic stationary phase improved peak efficiency and influenced chromatographic retention. The structures of pretreated SWNT and poly(VBC-EDMA-SWNT) monolith were examined by high-resolution transmission electron microscopy, Raman spectroscopy, scanning electron microscopy, and multipoint BET nitrogen adsorption/desorption.     

Phase-sensitive fluorescence lifetime detection in capillary electrophoresis

A simple and highly sensitive fluorescence lifetime detection method for capillary electrophoresis has been introduced. The detection scheme is based on the integrated phase-sensitive fluorescence intensity. The integrative nature of the method results in high sensitivity of lifetime detection. The limit of detection is 7.8 amol of fluorescein injected, representing a 2 orders of magnitude improvement over the detection limits previously reported in the UV-visible region. Rayleigh scattering, Raman scattering, and background fluorescence can be effectively suppressed by setting the detector out of the phase from the background signal. Fluorescence background can be eliminated whether the fluorescence lifetime of the background is longer or shorter than the solute molecules of interest. The signal-to-noise ratio of measurements is optimized by varying the modulation frequency and the detector phase angle.     

Microscopic origins of band broadening in chromatography. Polarity distribution in C(18) stationary phase probed by confocal ratiometric imaging of Nile red

Band broadening is a major factor that influences the efficiency and resolution of chromatographic separations. Studies of microscopic origins of band broadening, such as the micropolarity distribution of chromatographic stationary phase, can provide a better understanding of many chromatographic phenomena and retention behavior. In this work, we probe the chemical environments of C18 chromatographic stationary phase with quantitative confocal fluorescence microscopy under real reversed-phase liquid chromatography conditions. Ratiometric imaging of C18 interface is achieved by loading the stationary phase with a polarity-sensitive dye, Nile red, and optical sectioning with confocal microscopy. The results reveal that there are uniform micropolarity distributions inside individual chromatographic beads, but the polarity may differ between stationary-phase particles. The homogeneity of micropolarity of individual beads suggests that there are not any spatially large exposed silica sites beyond the optical resolution in C18 stationary phase. The strong adsorption sites are smaller in size than the optical resolution of a few hundred nanometers. The heterogeneity between chromatographic beads indicates that the interactions of Nile red with C18 bonded phase are different between beads. This contributes to the broad overall polarity distribution of the C18 stationary phase and can be one of the factors that cause band broadening in separations. With its high spatial resolution and optical sectioning capabilities, confocal fluorescence imaging is shown to be an ideal method to probe the chromatographic stationary phase. The distribution of micropolarity sheds light on the microscopic heterogeneity in chromatographic processes and its influence on chemical separations.     

Application of cyclam-capped beta-cyclodextrin-bonded silica particles as a chiral stationary phase in capillary electrochromatography for enantiomeric separations

Two novel types of substituted cyclam-capped beta-cyclodextrin (beta-CD)-bonded silica particles have been prepared and used as chiral stationary phases in capillary electrochromatography (CEC). The two stationary phases have a chiral selector with three recognition sites: beta-CD, cyclam, and the latter's sidearm. They exhibit excellent enantioselectivities in CEC for a wide range of compounds as a result of the cooperative functioning of the anchored beta-CD and cyclam. After inclusion of the metal ion (Ni2+) from the running buffer into the substituted cyclams and their sidearm ligands, the bonded stationary phases become positively charged and can provide extra electrostatic interactions with ionizable solutes and enhance the dipolar interactions with some polar neutral solutes. This enhances the host-guest interaction with some solutes and improves chiral recognition and enantioselectivity. These new types of stationary phases exhibit great potential for fast chiral separations in CEC.     

Characterization of the polarity of reversed-phase liquid chromatographic stationary phases in the presence of 1-propanol using solvatochromism and multivariate curve resolution

This work characterizes solvation effects in reversed-phase liquid chromatography in the presence of 1-propanol. The solvatochromic method combined with a multivariate curve resolution-alternating least-squares analysis method has been used to characterize two modified silica surfaces--phenyl bonded and C18 bonded silica in mobile-phase mixtures of methanol--water and acetonitrile--water in the presence of 1-propanol. The presence of a small amount of 1-propanol has been shown to affect mainly the polarity properties of the stationary phases while the mobile-phase properties are largely unaffected. The chain collapse mechanism for the C18 stationary phase at higher concentrations of water seems to be inhibited in the presence of 1-propanol, and partitioning is the predominant solute retention mechanism. The phenyl-based phase shows considerably different behavior from that of the C18 phase, and propanol appears to disrupt the pi-stacking interactions between the solute and the phenyl rings anchored to the silica support.     

An integrated fritless column for on-chip capillary electrochromatography with conventional stationary phases

A new polymer device for use with conventional particulate stationary phases for on-chip, fritless, capillary electrochromatography (CEC) has been realized. The structure includes an injector and a tapered column in which the particles of the stationary phase are retained and stabilized. The chips were easily fabricated in poly(dimethylsiloxane) using deep-reactive-ion-etched silicon masters, and tested using a capillary electrophoretic separation of FITC-labeled amino acids. To perform CEC, the separation channel was packed using a vacuum with 3-microm, octadecylsilanized silica microspheres. The packing was stabilized in the column by a thermal treatment, and its stability and quality were evaluated using in-column indirect fluorescence detection. The effects of voltage on electro-osmotic flow and on efficiency were investigated, and the separation of two neutral compounds was achieved in less than 15 s.     

Capillary electrochromatography of cannabinoids

The applicability of capillary electrochromatography (CEC) with photodiode array UV detection for the analysis of cannabinoids is presented. Baseline separation of seven cannabinoids (cannabigerol, cannabidiol, cannabinol, delta-9-tetrahydrocannabinol, delta-8-tetrahydrocannabinol, cannabichromene, delta-9-tetrahydrocannabinolic acid) is obtained using a 3-micron CEC Hypersil C18 capillary with an acetonitrile/phosphate (pH 2.57) mobile phase. The effects of acetonitrile concentration, buffer concentration, voltage, temperature, stationary phase, and column length on the separation of the cannabinoids were investigated. Good short- and long-term precision in retention times are observed, with significant improvement obtained using relative retention times with cannabinol as reference compound. Although short- and long-term peak area precisions are poor, satisfactory reproducibility is obtained using relative peak areas with cannabinol as reference compound. The applicability of the CEC methodology to drug seizures was demonstrated on marijuana and hashish. Using a high-sensitivity UV flow cell with an extended path length of 1.2 mm, concentration sensitivities approaching HPLC were obtained.     

Fabrication of graphene oxide nanosheets incorporated monolithic column via one-step room temperature polymerization for capillary electrochromatography

Graphene oxide (GO) has received great interest for its unique properties and potential diverse applications. Here, we show the fabrication of GO nanosheets incorporated monolithic column via one-step room temperature polymerization for capillary electrochromatography (CEC). GO is attractive as the stationary phase for CEC because it provides not only ionized oxygen-containing functional groups to modify electroendoosmotic flow (EOF) but also aromatic macromolecule to give hydrophobicity and π-π electrostatic stacking property. Incorporation of GO into monolithic column greatly increased the interactions between the tested neutral analytes (alkyl benzenes and polycyclic aromatics) and the stationary phase and significantly improved their CEC separation. Baseline separation of the tested neutral analytes on the GO incorporated monolithic column was achieved on the basis of typical reversed-phase separation mechanism. The precision (relative standard deviation (RSD), n = 3) of EOF was 0.3%, while the precision of retention time, peak area, and peak height for the tested neutral analytes were in the range of 0.4-3.0%, 0.8-4.0%, and 0.8-4.9%, respectively. In addition, a set of anilines were well separated on the GO incorporated monolith. The GO incorporated monolithic columns are promising for CEC separation.     

Capillary electrochromatography with fused-silica capillaries packed with copolymeric reversed-phase adsorbent and ion exchangers

Macroporous poly(styrene-divinylbenzene) (PSDVB), PRP-1, a reversed-phase adsorbent, and PSDVB-based strong acid cation exchangers and strong base and weak base anion exchangers were evaluated as stationary phases for capillary electrochromatography (CEC). Electroosmotic flow (EOF) for adsorbent and exchanger packed fused-silica capillaries for acetone as the marker increases with increasing ion exchange capacity, buffer organic solvent concentration, and applied voltage, is nearly independent of pH, and decreases with increased buffer ionic strength. For anion exchangers, EOF is reversed. Thiourea, acetone, acrylamide, nitromethane, propanal, and acetic acid were evaluated as EOF markers and undergo weak interaction with the PSDVB-based stationary phases. EOF in a basic buffer is greater than or equal to silica-based C-18 and cation exchanger packed capillaries. For an acidic buffer, EOF for a PRP-1 capillary is almost twice the C-18 packed capillary. As analyte hydrophobicity increases, retention and migration time increases for the PSDVB-based stationary phases. As exchange capacity increases, availability of the polymeric matrix for analyte partitioning decreases, causing analyte migration time to decrease. Increasing buffer organic solvent concentration decreases analyte retention. The PSDVB-based stationary phases provide good resolving power and reproducibility and are applicable to the CEC separation of neutral, weakly acidic, and basic analytes. Efficiency, however, is less than obtained with silica-based stationary phases. Because of stability in a strong acid buffer, the CEC separation of weak acids, where dissociation is suppressed, and weak bases as cations is possible. Separations of short-chain alkyl aldehydes, methyl ketones, aromatic hydrocarbons, substituted benzene derivatives, and short-chain carboxylic acids are described.     

Capillary electrochromatography for separation of peptides driven with electrophoretic mobility on monolithic column.

A mode of capillary electrochromatography for separation of ionic compounds driven by electrophoretic mobility on a neutrally hydrophobic monolithic column was developed. The monolithic column was prepared from the in situ copolymerization of lauryl methacrylate and ethylene dimethacrylate to form a C12 hydrophobic stationary phase. It was found that EOF in this hydrophobic monolithic column was very poor, even the pH value of mobile phase at 8.0. The peptides at acidic buffer were separated on the basis of their differences in electrophoretic mobility and hydrophobic interaction with the stationary phase; therefore, different separation selectivity can be obtained in CEC from that in capillary zone electrophoresis (CZE). Separation of peptides has been realized with high column efficiency (up to 150,000 plates/meter) and good reproducibility (migration time with RSD <0.5%), and all of the peptides, including some basic peptides, showed good peak symmetry. Effects of the mobile phase compositions on the retention of peptides at low pH have been investigated in a hydrophobic capillary monolithic column. The significant difference in selectivity of peptides in CZE and CEC has been observed. Some peptide isomers that cannot be separated by CZE have been successfully separated on the capillary monolithic column in this mode with the same buffer used.     

On-column trace enrichment by sequential frontal and elution electrochromatography. 1. Application to carbamate insecticides

An on-column trace enrichment method for CEC of dilute samples is presented. The method involves on-line preconcentration by frontal electrochromatography under conditions of strong solute binding to the stationary phase followed by a step-gradient elution electrochromatography with a mobile phase of high eluting strength. This method is tested with dilute samples of carbamate insecticides using capillary columns of 100-microm i.d. packed with a 5-microm octadecyl silica (ODS) stationary phase. The effectiveness of on-line preconcentration (i.e., zone narrowing) depends on the retention factor, k', of the analyte in the injection solvent as well as in the eluting mobile phase (i.e., the organic solvent content), the applied voltage during sample introduction, and elution and length of the introduced sample plug. Under optimal frontal and elution electrochromatography conditions, a 500-fold sensitivity increase is achieved for carbofuran (a carbamate insecticide) with a UV detector. The method is demonstrated with deionized and tap water samples spiked with carbamate insecticides.     

Separation of tocopherol isomers using capillary electrochromatography: comparison of monomeric and polymeric C30 stationary phases.

The comparison of tocopherol isomer separation achieved using different stationary-phase alkyl chain lengths (i.e., C18 vs C30) and modes of alkyl phase attachment to the silica-based supports (i.e., polymeric vs monomeric synthesis) using capillary electrochromatography (CEC) has been demonstrated. The smaller alkyl chain does not exhibit the shape selectivity needed to resolve all of the tocopherol isomers. Conversely, both polymeric and monomeric C30 phases show increased tocopherol isomer selectivity. Changing the elutropic strength of the mobile phase had dramatic effects on the selectivity, with small additions of water to a methanol mobile phase yielding the best selectivity. The complete baseline separation of the tocopherol isomers was achieved using the monomerically bound C30 stationary phase and a methanol/ water mobile phase. The differences in stationary-phase selectivity were examined using a NIST standard reference material for determining column selectivity in LC. The results indicated that the monomeric C30 actually had "intermediate" phase characteristics (i.e., high phase loading, end capping, etc). This new CEC-based separation was also used to separate the tocopherols in a vitamin E supplement sample.     

Simultaneous separation of acidic, basic, and neutral organic compounds, including strong and moderate acids and bases, by capillary electrochromatography

The separation of strongly basic, moderately basic, weakly basic, strongly acidic, moderately acidic, weakly acidic, and neutral compounds in a single run using capillary electrochromatography (CEC) is presented. This is accomplished using a 3-μm CEC Hypersil C8 capillary with high organic content acetonitrile/phosphate (pH 2.5) mobile phases containing hexylamine. Fifteen basic, acidic, and neutral drugs of forensic interest are resolved using a step gradient. Strong and moderately basic drugs separate before t(o), apparently by a combination of free zone electrophoresis (CZE) and chromatographic phenomena. Weak bases separate after t(o), also by a combination of CZE and chromatographic processes. Due to large selectivity differences between CEC and CZE for bases, there is evidence that the stationary phase is playing a significant role in the separation of these solutes. The CEC approach presented offers unique selectivity, expanded peak capacity, and the ability to solubilize both hydrophilic and hydrophobic solutes in an injection solvent that is compatible with the chromatographic system.     

Immobilized ionic liquids as high-selectivity/high-temperature/high-stability gas chromatography stationary phases

Ionic liquids (ILs) are a class of nonmolecular solvents in which the cation/anion combination can be easily tuned to provide desired chemical and physical properties. When used as stationary phases in gas-liquid chromatography, ionic liquids exhibit dual nature retention selectivity. That is, they are able to separate polar molecules such as a polar stationary phase and nonpolar molecules such as a nonpolar stationary phase. However, issues such as optimization of the wetting ability of the ionic liquid on fused-silica capillaries, the maximum operating temperatures of the stationary phases, and nonuniform film thickness on the wall of the capillary at high temperatures have limited their use in gas chromatography. As described in this paper, these limitations are overcome by cross-linking a new class of ionic liquid monomers by free radical reactions to provide a more durable and robust stationary phase. By lightly cross-linking the ionic liquid stationary phase using a small amount of free radical initiator, high-efficiency capillary columns were produced that are able to endure high temperatures with little column bleed. Two types of cross-linked IL stationary phases are developed. A partially cross-linked stationary phase allows for high-efficiency separations up to temperatures of approximately 280 degrees C. However, by creating a more highly cross-linked stationary phase of geminal dicationic ILs, exclusively, an increase in efficiency is observed at high temperatures allowing for its use over 350 degrees C. In addition, through the use of solvation thermodynamics and interaction parameters, it was shown that the cross-linking/immobilization of the ionic liquid does not affect the selectivity of the stationary phase thereby preserving its dual nature retention behavior.     

On-the-fly fluorescence lifetime detection of humic substances in capillary electrophoresis

On-the-fly fluorescence lifetime detection was investigated as a tool for studying humic substances in capillary zone electrophoresis (CZE). Humic substances are complex, heterogeneous mixtures of natural products that tend to migrate in a single, broad CZE peak. The intrinsic fluorescence lifetime of five humic substances from the International Humic Substances Society (IHSS) was monitored using excitation at 488 or 364 nm to produce intensity-lifetime electropherograms for each of the substances. Each frequency-domain lifetime measurement, collected at subsecond intervals during the CZE run, contains the equivalent of a complete decay profile. Lifetime analysis of each decay profile was used to construct a lifetime-resolved electropherogram for each lifetime component, from which the variation in relative intensity contributions of each lifetime across the broad CZE peak could be determined. Absorption spectra, fluorescence excitation-emission spectra, and lifetime profiles of batch solutions of the samples were determined as well. It was found that, whereas absorption and fluorescence spectral characteristics tended to discriminate between humic acids and fulvic acids, the batch solution lifetime profiles discriminated instead between samples from different sources, regardless of fraction. On-the-fly lifetime detection provided a more detailed view of the fluorescence decay of the samples, including greater resolution of lifetimes for two of the fulvic acids and greater discrimination among samples based on lifetime profiles across the CZE peaks.     

Monolithic column with zwitterionic stationary phase for capillary electrochromatography

A capillary electrochromatography (CEC) monolithic column with zwitterionic stationary phases was prepared by in situ polymerization of butyl methacrylate, ethylene dimethacrylate, methacrylic acid, and 2-(dimethyl amino) ethyl methacrylate in the presence of porogens. The stationary phases have zwitterionic functional groups, that is, both tertiary amine and acrylic acid groups, so the ionization of those groups on the zwitterionic stationary phase was affected by the pH values of the mobile phase, and further affects the strength and direction of the electroosmotic flow (EOF). Separations of alkylbenzenes and polycyclic aromatic hydrocarbons based on the hydrophobic mechanism were obtained. Separation of various types of polar compounds, including phenols, anilines, and peptides, on the prepared column were performed under CEC mode with anodic and cathodic EOF, and different separation selectivities of those polar analytes were observed on the monolithic capillary column by using mobile phases with different pH values.     

Fritless packed columns for capillary electrochromatography: separation of uncharged compounds on hydrophobic hydrogels

A novel column is described that does not require frits to keep packing material within a capillary. A continuous bed is prepared in situ in aqueous solution by radical copolymerization of N-isopropylacrylamide and 2-acrylamido-2-methylpropanesulfonic acid (the resultant gel is denoted poly(AMPS-co-IPAAm). N,N'-Methylenebisacrylamide is used for cross-linking. On the application of an electrical field, electroosmotic flow (EOF) is developed in the bed along the capillary, where fluid propulsion would be otherwise difficult to achieve. The resultant EOF transports neutral compounds through the column without forcing the gel out of the capillary. Examination of the fluid motion in the continuous bed using a video microscope system and an image processor shows a relatively flat flow profile of EOF. The bed functions as the stationary phase for reversed-phase capillary electrochromatography (CEC). This new approach is an alternative to packed capillary columns which have been used previously in CEC. A high efficiency is obtained for a steroid which is separated on a 4.0% total monomer concentration (T), 10.0% degree of cross-linking (C), and 10.0% mole fraction of AMPS in the total monomer (S), poly(AMPS-co-IPAAm) column. A mixture of polyaromatic hydrocarbons is separated on a 6.9% T, 5.8% C, and 5.5% S poly(AMPS-co-IPAAm) column. The capacity factor of benzo[a]pyrene increases from 0.63 to 1.91 as the acetonitrile content in a Tris-boric acid buffer is decreased from 45 to 30% (v/v). The run-to-run RSD of analyte migration time is less than 0.73%, and the day-to-day RSD is acceptable. Potential benefits of this approach are also mentioned.     

C60 and C70 HPLC retention reversal study using organic modifiers

A novel equation (Guillaume Y. C. et al. Anal. Chem. 1998, 70, 608) modeling the weak polar solute retention in reversed-phase liquid chromatography (RPLC) was applied to fullerene molecules C60 and C70. In RPLC, with an organic modifier (OM)/water mobile phase, the fullerene cluster solvation energies were calculated for OM = methanol, ethanol, propanol, butanol, and pentanol. An enthalpy-entropy compensation revealed that the type of interactions between fullerenes and the stationary phase was independent of both the fullerene and organic modifier structures. The energetics of OM and OM-water cluster exchange processes in the mobile phase were investigated in relation to the carbon atom number of the hydrophobic chain of the OM. Two linear correlations were found between the Gibbs free energy changes in the solvent exchange processes which confirmed that (i) a reversal elution order existed for C60 and C70 when methanol was changed into ethanol, propanol, butanol, pentanol and that (ii) the mobile phase was dominant in governing selectivity changes in nonpolar solutes.