Fluorescence polarization detection for affinity capillary electrophoresis

Affinity capillary electrophoresis (ACE) with laser-induced fluorescence polarization (LIFP) detection is described, with examples of affinity interaction studies. Because fluorescence polarization is sensitive to changes in the rotational motion arising from molecular association or dissociation, ACE-LIFP is capable of providing information on the formation of affinity complexes prior to or during CE separation. Unbound, small fluorescent probes generally have little fluorescence polarization because of rapid rotation of the molecule in solution. When the small fluorescent probe is bound to a larger affinity agent, such as an antibody, the fluorescence polarization (and anisotropy) increases due to slower motion of the much larger complex molecule in the solution. Fluorescence polarization results are obtained by simultaneously measuring fluorescence intensities of vertical and horizontal polarization planes. Applications of CE-LIFP to both strong and weak binding systems are discussed with antibody-antigen and DNA-protein binding as examples. For strong affinity binding, such as between cyclosporine and its antibody, complexes are formed prior to CE-LIFP analysis. For weaker binding, such as between single-stranded DNA and its binding protein, the single-stranded DNA binding protein is added to the CE separation buffer to enhance dynamic formation of affinity complexes. Both fluorescence polarization (and anisotropy) and mobility shift results are complementary and are useful for immunoassays and binding studies.     

Fluorescence detection with an immersed flow cell in capillary electrophoresis

An immersed flowcell has been developed for fluorescence detection in capillary electrophoresis (CE) by modifying an ordinary HPLC spectrofluorimetric detector flowcell. The minimum detectability obtained for riboflavine was about 4 fmol. The use of the flowcell to measure a fluorescence spectrum by the stopped-flow method of shutting down the DC high voltage during a wavelength scan, has also been achieved successfully.     

Fluorescence line-narrowing spectroscopy of fluorene and naphthalene with second-harmonic generated ultraviolet radiation

Second-harmonic generated u.v. radiation from an argon-ion pumped CW dye laser is used to yield highly resolved fluorescence line-narrowed spectra of fluorene and naphthalene in 3-methylpentane at 10 K and 5 K, respectively. The results suggest that the applicability of the method can be widely extended.     

The applicability of fluorescence line-narrowing spectroscopy in combination with thin-layer chromatography

Laser excitation at low temperatures of compounds on thin-layer chromatographic plates yields, also after elution, highly resolved spectra. The fluorescence line-narrowed spectra permit identification of spectroscopically alike compounds, as is demonstrated for pyrene and halogenated pyrenes. Detection limits are in the low nanogram region even with relatively simple instrumentation. It is shown that quantitative application is possible if an internal standard is used.     

Fluorescence detection in capillary electrophoresis using a variable wavelength epi-fluorescence microscope

A capillary electrophoresis fluorescence detector is described. A high-pressure mercury lamp with a filter block allowed the selection of a particular excitation waveband. Detection was performed on-column, the fluorescence emission was monitored and measured with a silicon photodiode detector with a built-in amplifier. The concentration limit of detection (CLOD) of 0.4 ng/mL was obtained for rhodamine B, a fluorescent indicator. Based on an estimated injection volume of 2.5 nL, the mass limit of detection (MLOD) was 2.1×10^–18 mol. The separation of three fluorescent indicators: thionine, eosin yellowish and rhodamine B, was achieved in less than 6 min. The separation of nine porphyrin-free acids using the system developed was also demonstrated. The advantages and potential of using an epi-illumination microscope as a versatile and sensitive fluorescence detection system for capillary electrophoresis are described.     

A review of pulsed electrochemical detection following liquid chromatography and capillary electrophoresis

Pulsed electrochemical detection (PED) has progressed as a highly sensitive and selective detection technique following aqueous-based separation systems over the past three decades. The application of on-line pulsed potential cleaning to electrocatalytic noble metal electrodes has significantly increased the number of applications formerly achieved with conventional electrochemical (EC) detection. Electrochemical cells are easily miniaturized, providing the ability to apply detection by PED at microelectrodes and onto microchips utilizing electrophoretic separations. In addition, recent advances in PED waveforms and instrumentation have enabled the detection technique to be easily coupled with high pressure separation systems which require rapid detection to maintain separation integrity. As a result, advanced applications for the determination of carbohydrates as well as the expansion of PED for the detection of other organic aliphatic compounds have been recently accomplished. This review will focus on developments and methods utilizing PED following liquid chromatography (LC) and capillary electrophoresis (CE). Publications are reviewed in chronological order to emphasize the advancement of the detection method and the sustained relevance of its applications.     

Analytical potential of mid-infrared detection in capillary electrophoresis and liquid chromatography: a review

Literature published in the last decade concerning the use of mid-infrared spectrometry as a detection system in separation techniques employing a liquid mobile phase is reviewed. In addition to the continued use of isocratic liquid chromatographic (LC) techniques, advances in chemometric data evaluation techniques now allow the use of gradient techniques on a routine basis, thus significantly broadening the range of possible applications of LC-IR. The general trend towards miniaturized separation systems was also followed for mid-IR detection where two key developments are of special importance. Firstly, concerning on-line detection the advent of micro-fabricated flow-cells with inner volumes of only a few nL for transmission as well as attenuated total reflection measurements enabled on-line mid-IR detection in capillary LC and opened the path for the first successful realization of on-line mid-IR detection in capillary zone electrophoresis as well as micellar electrokinetic chromatography. Secondly, concerning off-line detection the use of micro-flow through dispensers now enables to concentrate eluting analytes on dried spots sized a few tens of micrometers, thus matching the dimensions for sensitive detection by mid-IR microscopy. Finally in an attempt to increase detection sensitivity of on-line mid-IR detection, mid-IR quantum cascade lasers have been used. Applications cover the field of food analysis, environmental analysis and the characterization of explosives among others. Best detection sensitivities for on-line and off-line detection have been achieved in miniaturized systems and are in the order of 50 ng and 2 ng on column, respectively.     

Pharmacokinetic study of metoprolol in rabbit plasma by capillary electrophoresis with laser-induced Fluorescence detection

This work described a sensitive method for determination of metoprolol in rabbit plasma. The method involved purification by ultrafiltration, derivatization with Fluorescein isothiocyanate, separation by capillary electrophoresis and determination by laser-induced fluorescence detector. Other components in plasma including a variety of amino acids and proteins did not interfere with the determination of metoprolol under experimental conditions. The assay had a wide range (2.0?C500 ng/mL) of linearity and a detection limit of 0.8 ng/mL. The intra- and inter-day precisions of the QC samples were satisfactory with RSD less than 10% and accuracy within 10%. This method was successfully applied to pharmacokinetic study of metoprolol in rabbit blood.     

Fluorescence detection and identification of eight sulphonamides using capillary electrophoresis on released excipients in lake water

A simple and sensitive capillary electrophoresis method with fluorescence detection was developed for the determination of sulphanilamide, sulphamerazine, sulphacetamide and sulphanilic acid, sulphathiazole, Sulphisomidine, sulphadoxine and sulphadiazine in lake water. The sulphonamides were extracted from lake water, derivatized with fluorescamine and determination of sulphonamide was achieved using 20 mM borate buffer of pH 9.5 at an applied voltage of 25 kV. Detection was performed using UG-11 excitation filter of 405 nm and 495 nm emission filters. A fast, simple and sensitive method with limit of detection in the range 0.89–1.43 n mol L⁻¹ for all the eight sulphonamides with good recoveries of 80–110% is seen. Inter-day and intra-day validation of the separation method shows fairly good results. The detection and quantification limits for this newly developed method are too low to determine drug residues in lake water.     

Optimization methods in chromatography and capillary electrophoresis

Many methods have been developed in order to optimize the parameters of interest in either chromatography or capillary electrophoresis. In chemometric approaches experimental measurements are performed in such a way that all factors vary together. An objective function is utilized in which the analyst introduces the desired criteria (selectivity, resolution, time of analysis). Simplex methods and overlapping resolution maps are declining. Factorial designs and central composite designs are more and more popular in electrodriven capillary separations since the number of parameters to master is much larger than in either GC or LC. The use of artificial neural networks is increasing. The advantage of chemometrics tools is that no explicit models are required, conversely the number of experiments to perform may be high and boundaries of the domain are not straightforward to draw and the approach does more than is required. When models are available optimization is easier to perform by regression methods. Computer assisted methods in RPLC are readily available and work well but are still in infancy in CE. Linear solvation energy relationships seem a very valuable tool but estimates of coefficients still require many experiments.     

Determination of recent antidepressant citalopram in human plasma by liquid chromatography—Fluorescence detection

Summary A reliable and sensitive high-performance liquid chromatographic method for the determination of the recent antidepressant citalopram and two metabolites in human plasma has been developed. Fluorescence detection at 300 nm was used, exciting at 238 nm. Separation was obtained using a reversed-phase column (C18, 250 × 3.0 mm i.d., 5 μm) and a mobile phase. 40% acetonitrile: 60% aqueous tetramethylammonium perchlorate (pH 1.9). Calibration curves were linear over a working range: 5–300 ng mL⁻¹ for citalopram, 2.5–150.0 ng mL⁻¹ for desmethylcitalopram and 2.5–50.0 ng mL⁻¹ for didesmethylcitalopram. The limits of quantitation (LOQ) were 1.5 ng mL⁻¹ for citalopram and desmethylcitalopram and 2.0 ng mL⁻¹ for didesmethylcitalopram. Precision data, as well as accuracy, were satisfactory and no interference from different psychotropic drugs was found. The method was therefore suitable for therapeutic drug monitoring of citalopram and its active metabolites in plasma of depressed patients.     

Non-linear line-narrowing spectroscopy in mixed organic crystals

We report the elimination of inhomogeneous broadening in mixed organic crystals with multiply resonant four-wave mixing methods. Line narrowing and the line shifts characteristic of site selective methods are observed for both coherent anti-Stokes Raman spectroscopy (CARS) and multiply enhanced non-parametric spectrosocopy (MENS). The site selective capability of CARS is in agreement with the model proposed by Ouellette and Denariez-Roberge.     

Capillary liquid chromatography of multiple peptides with on-line capillary electrophoresis immunoassay detection.

A competitive immunoassay for neuropeptide Y (NPY) based on capillary electrophoresis (CE) with laser-induced fluorescence detection was developed utilizing polyclonal antisera as the immunoreagent and fluorescein-labeled NPY as the tracer. The assay was performed with on-line mixing of reagents, automated injections, and a 3 s separation time. The assay had a detection limit of 850 pM. To detect NPY at lower concentrations, the assay was coupled on-line to reversed-phase capillary liquid chromatography (LC). In this arrangement, 5 microL samples were preconcentrated by capillary LC and eluted by a gradient of isopropanol-containing mobile phase. The resulting chromatographic peaks were monitored by the CE immunoassay. With preconcentration, the concentration detection limit was improved to 40 microM and NPY could be measured in push-pull perfusion samples collected from the paraventricular nucleus of freely moving rats. The technique was extended to simultaneous detection of NPY and glucagon secretion from islets of Langerhans.     

Pharmaceutical applications of micelles in chromatography and electrophoresis

This review surveys the use of micelles as separation media in chromatography and electrophoresis. Applications to pharmaceuticals whose molecular masses are relatively small are focused on in this review. In high-performance liquid chromatography (HPLC), chromatography using micelles and reversed-phase stationary phases such as octadecylsilylized silica gel (ODS) columns is known as micellar liquid chromatography (MLC). The main application of MLC to pharmaceutical analysis is the same as in ion-pair chromatography using alkylsulfonate or tetraalkylammonium. In most cases, selectivity is much improved compared with other short alkyl chain ion-pairing agents such as pentanesulfonate or octanesulfonate. Direct plasma/serum injection can be successful in MLC. Separation of small ions is also successful by using gel filtration columns and micellar solutions. In electrophoresis, especially capillary electrophoresis (CE), micelles are used as pseudo-stationary phases in capillary zone electrophoresis (CZE). This mode is called micellar electrokinetic chromatography (MEKC). Most of the drug analysis can be performed by using the MEKC mode because of its wide applicability. Enantiomer separation, separation of amino acids and closely related peptides, separation of very complex mixtures, determination of drugs in biological samples etc. as well as separation of electrically neutral drugs can be successfully achieved by MEKC. Microemulsion electrokinetic chromatography (MEEKC), in which surfactants are also used in forming the microemulsion, is successful for the separation of electrically neutral drugs as in MEKC. This review mainly describes the typical applications of MLC and MEKC for the analysis of pharmaceuticals.     

Using dendrimers and hyperbranched polymers in chromatography and electrophoresis

The use of a new class of high-molecular-weight substances, dendritic polymers (dendrimers and hyperbranched polymers), as components of chromatographic and electrophoretic systems is discussed; the effect of their introduction into a background electrolyte or an eluent on the separation efficiency and selectivity of organic compounds of different classes is considered.     

Advances in capillary electrophoresis: the challenges to liquid chromatography and conventional electrophoresis

In the 1980s, capillary electrophoresis (CE) developed rapidly into a first-class analytical separation technique. Its advances in instrumentation and method development will not only enhance or complement existing mature separation techniques such as liquid chromatography and conventional slab gel electrophoresis, but will also severely challenge these separation methods. A brief overview of the most striking achievements of CE in the 1980s is given. which illustrates the challenges to liquid chromatography and conventional slab gel electrophoresis, and some detailed discussions are presented to highlight the advantages of CE. New developments in CE that can be expected for the 1990s include especially column technology, separation chemistry and instrumentation, which will serve further to diversify and improve the applicability of this technique in areas which are poorly addressed by other separation methods. This paper considers and speculates on the technological advancements that can be expected to emerge for CE in the 1990s.     

Conductivity detection in capillary electrophoresis

Among electrochemical detection methods in capillary electrophoresis, conductometric methods are of specific interest for the determination of inorganic species. This is due to the fact that inorganic ions exhibit a high equivalent conductivity which corresponds to the analytical signal in conductivity detection. Indirect optical absorption methods, which are widely used in capillary electrophoretic ion analyses, become less sensitive with smaller capillary dimensions and thus have disadvantages in electrokinetic chip separation technologies.Conductivity detection for capillary electrophoresis is performed either through galvanic contact or in a contactless mode. Techniques using a galvanic contact of the sample ions with the measuring electrode are performed either on-capillary without decoupling of the separation high voltage, or off-capillary after grounding the separation voltage in order to avoid interferences. This technology is specifically important when a suppressor is used prior to detection. Most contactless methods use oscillometric techniques in order to obtain the analytical signal.This review discusses the theoretical and instrumental background of conductivity detection in capillary electrophoresis and reports on recent aspects and applications using conductometric detection methods for capillary zone electrophoresis.