On-column electrochemical detection for microchip capillary electrophoresis

The development of a cellulose acetate decoupler for on-column electrochemical detection in microchip capillary electrophoresis is presented. The capillary based laser-etched decoupler is translated to the planar format to isolate the detector circuit from the separation circuit. The decoupler is constructed by aligning a series of 20 30-microm holes through the coverplate of the microchip with the separation channel and casting a thin film of cellulose acetate within the holes. The decoupler shows excellent isolation of the detection circuit for separation currents up to 60 microA, with noise levels at or below 1 pA at a carbon fiber electrode. Detection limits of 25 nM were achieved for dopamine. This decoupler design combines excellent mechanical stability, effective shunting of high separation currents, and ease of manufacture.     

Dual-channel method for interference-free in-channel amperometric detection in microchip capillary electrophoresis

A novel in-channel amperometric detection method for microchip capillary electrophoresis (CE) has been developed to avoid the interference from applied potential used in the CE separation. Instead of a single separation channel as in conventional CE microchips, we use a dual-channel configuration consisting of two different parallel separation and reference channels. A working electrode (WE) and a reference electrode (RE) are placed equally at a distance 200 microm from its outlet on each channel. Running buffer flows through the reference channel. Our dual-channel CE microchips consist of a poly(dimethylsiloxane) (PDMS) upper plate and a glass lower plate to form a PDMS/glass hybrid chip. Amperometric signals are measured without any potential shift and interference from the applied CE potential, and CE separation maintains its high resolution because this in-channel configuration does not allow additional band broadening that is notorious in end-channel and off-channel configurations. The high performance of this new in-channel electrochemical detection methodology for CE has been demonstrated by analyzing a mixture of electrochemically active biomolecules: dopamine (DA), norepinephrine, and catechol. We have achieved a 0.1 pA detectability from the analysis of DA, which corresponds to a 1.8 nM concentration.     

High-voltage capacitively coupled contactless conductivity detection for microchip capillary electrophoresis

Contactless conductivity detection was carried out on a planar electrophoresis device by capacitive coupling using an ac excitation voltage of 500 V(p-p) and a frequency of 100 kHz. It was possible to carry out detection in this way through a cover plate of 1 mm thickness. Better sensitivity is obtained, however, by placing the electrodes into troughs that allow tighter coupling to the separation channel. The 3 x S/N detection limits are 0.49, 0.41, and 0.35 microM for the small inorganic ions K+, Na+, and Mg2+. The detection of heavy metals is demonstrated with the example of Mn2+, Zn2+, and Cr3+ with detection limits of 2.1, 2.8, and 6.8 microM, respectively. The universal nature of the method is further illustrated by the detection of citric and lactic acids, which are of interest in food and beverage analysis, and detection of three antiinflammatory nonsteroid drugs, 4-acetamidophenol, ibuprofen, and salicylic acid, as examples of species of pharmaceutical interest.     

Dual conductivity/amperometric detection system for microchip capillary electrophoresis

The performance characteristics and advantages of a new dual electrochemical microchip detection system based on simultaneous conductivity and amperometric measurements are described. The system relies on the combination of a contactless conductivity detector with an end-column thick-film amperometric detector. Such coupling of the conductivity and amperometric detection modes in a single separation channel greatly enhances the sample characterization to offer simultaneous measurements of both ionic and electroactive species, improved reproducibility, and confirmation of peak identity. The simultaneous measurement of nitroaromatic and ionic explosives is used for demonstrating the ability to detect both electroactive and ionic species. Major improvements are also observed for analytes responding at both detectors. For example, the generation of dual response ratios can be used to improve the reproducibility and confirm the peak identity/integrity. Such dual response ratios reflect the distinct redox and conductivity properties of the individual analytes. The independence of the two detectors is reflected in the absence of "cross-talk" effects. The behavior of the dual detector is comparable with those of the individual detectors. Such a dual electrochemical detection system is easy to implement and requires inherently portable low-cost instrumentation.     

Instrumentation for medium-throughput two-dimensional capillary electrophoresis with laser-induced fluorescence detection

In two-dimensional capillary electrophoresis, a sample undergoes separation in the first dimension capillary by sieving electrophoresis. Fractions are periodically transferred across an interface into a second dimension capillary, where components are further resolved by micellar electrokinetic capillary electrophoresis. Previous instruments employed one pair of capillaries to analyze a single sample. We now report a multiplexed system that allows separation of five samples in parallel. Samples are injected into five first-dimension capillaries, fractions are transferred across an interface to 5 second-dimension capillaries, and analyte is detected by laser-induced fluorescence in a five-capillary sheath-flow cuvette. The instrument produces detection limits of 940 +/- 350 yoctomoles for 3-(2-furoyl)quinoline-2-carboxaldehyde labeled trypsin inhibitor in one-dimensional separation; detection limits degrade by a factor of 3.8 for two-dimensional separations. Two-dimensional capillary electrophoresis expression fingerprints were obtained from homogenates prepared from a lung cancer (A549) cell line, on the basis of capillary sieving electrophoresis (CSE) and micellar electrophoresis capillary chromatography (MECC). An average of 131 spots is resolved with signal-to-noise greater than 10. A Gaussian surface was fit to a set of 20 spots in each electropherogram. The mean spot width, expressed as standard deviation of the Gaussian function, was 2.3 +/- 0.7 transfers in the CSE dimension and 0.46 +/- 0.25 s in the MECC dimension. The standard deviation in spot position was 1.8 +/- 1.2 transfers in the CSE dimension and 0.88 +/- 0.55 s in the MECC dimension. Spot capacity was 300.     

Dual fluorescence and electrochemical detection on an electrophoresis microchip

Simultaneous amperometric and fluorescence detection in a microfabricated electrophoresis chip is reported. Detection limits of 448 nM and 1.52, 16, and 28 microM have been achieved for dopamine, catechol, NBD-arginine, and NBD-phenylalanine, respectively. These two orthogonal detection schemes allow analysis of a wider spectrum of compounds per separation, leading to higher throughput and enabling resolution of two neutral analytes, NBD-arginine and catechol. In addition, insight into the detection and separation mechanisms is realized. Differences in migration time and peak widths between the two detectors are compared, providing a better understanding of detector alignment. A common problem encountered in electrophoresis is run-to-run migration time irreproducibility for certain samples. This novel microchip dual detection system has been utilized to reduce this irreproducibility. An unknown sample is monitored with one detector while a standard (i.e., ladder) is added to the sample and monitored simultaneously with the other detector. This dual detection method is demonstrated to normalize unknown peak mobilities in a cerebral spinal fluid sample.     

Gold nanoparticle-enhanced microchip capillary electrophoresis

We describe here the use of gold nanoparticles in conjunction with chip-based capillary electrophoresis to improve the selectivities between solutes and to increase the efficiency of the separation. We coated the microchannel wall of a microfluidic device with a layer of poly(diallyldimethylammonium chloride) (PDADMAC) and then collected on it citrate-stabilized gold nanoparticles. The resolutions and the plate numbers of the solutes were doubled in the presence of the gold nanoparticles. Such selectivity improvements reflect changes in the observed mobility accrued from interactions of solutes with the particle surface. The electrochemical detection and the quantitation of the solutes were not effected by the PDADMAC and the gold nanoparticles.     

DNA sequencing by capillary electrophoresis with four-decay fluorescence detection

A scheme for multiplex detection of dye-labeled DNA fragments in DNA sequencing is described in which on-the-fly, frequency-domain fluorescence lifetime detection is used to discriminate among the dye-labeled fragments of the four terminal bases in a single-lane CE separation. Two four-dye systems were evaluated, one excited at 488 nm and the other, at 514 nm. The 488 nm system proved successful for four-decay detection. Base calling was achieved either directly from on-the-fly lifetimes or from lifetime-resolved electropherograms recovered for each base from the electropherogram of the mixture of sequencing reaction products. The latter method was found to be more accurate (99% for two bases and 98.5% for three bases) and could achieve longer read lengths, but it was unsuccessful for sequencing of all four bases. The first method gave a base-calling accuracy of 96% for four-base sequencing over the fragment length range of 41-220 bases.     

Movable contactless-conductivity detector for microchip capillary electrophoresis

A new movable contactless-conductivity detection system for microchip capillary electrophoresis is introduced. Such a versatile system relies on positioning the detector at different points along the separation channel via "sliding" the electrode holder. The new movable microchip detection system offers distinct improvements compared to common fixed-location conductivity detectors. For example, placing the detector at different locations along the microchannel offers useful insights into the separation process. Three-dimensional plots of resolution/channel length/separation voltage can be used for optimizing the separation process and selecting the analysis time. The system enables rapid switching between "total" (unresolved) and "individual" (resolved/fingerprint) signals on the basis of placing the detector at the beginning and end of the separation channel, respectively. By moving the detector to a shorter effective separation length, after eluting fast-migrating ions, shorter analysis times can be achieved (through faster detection of late-eluting analytes). These and other improvements in the analytical performance and insights into the separation process are illustrated in connection with the detection of low-energy ionic explosives and nerve agent degradation products.     

Portable high-voltage power supply and electrochemical detection circuits for microchip capillary electrophoresis

Miniaturized, battery-powered, high-voltage power supply, electrochemical (EC) detection, and interface circuits designed for microchip capillary electrophoresis (CE) are described. The dual source CE power supply provides +/- 1 kVDC at 380 microA and can operate continuously for 15 h without recharging. The amperometric EC detection circuit provides electrode potentials of +/-2 VDC and gains of 1, 10, and 100 nA/V. The CE power supply power is connected to the microchip through an interface circuit consisting of two miniature relays, diodes, and resistors. The microchip has equal length buffer and separation channels. This geometry allows the microchip to be controlled from only two reservoirs using fixed dc sources while providing a consistent and stable sample injection volume. The interface circuit also maintains the detection reservoir at ground potential and allows channel currents to be measured likewise. Data are recorded, and the circuits are controlled by a National Instruments signal interface card and software installed in a notebook computer. The combined size (4 in. x 6 in. x 1 in.) and weight (0.35 kg) of the circuits make them ideal for lab-on-a-chip applications. The circuits were tested electrically, by performing separations of dopamine and catechol EC and by laser-induced fluorescence visualization.     

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.     

In-channel electrochemical detection for microchip capillary electrophoresis using an electrically isolated potentiostat

A new electrode configuration for microchip capillary electrophoresis (CE) with electrochemical (EC) detection is described. This approach makes it possible to place the working electrode directly in the separation channel. The "in-channel" EC detection was accomplished without the use of a decoupler through the utilization of a specially designed, electrically isolated potentiostat. The effect of the working electrode position on the separation performance (in terms of plate height and peak skew) of poly(dimethylsiloxane)-based microchip CEEC devices was evaluated by comparing the more commonly used end-channel configuration with this new in-channel approach. Using catechol as the test analyte, it was found that in-channel EC detection decreased the total plate height by a factor of 4.6 and lowered the peak skew by a factor of 1.3. A similar trend was observed for the small, inorganic ion nitrite. Furthermore, a fluorescent and electrochemically active amino acid derivative was used to directly compare the separation performance of in-channel EC detection to that of a widely used laser-induced fluorescence (LIF) detection scheme. In this case, it was found that the plate height and peak skew for both detection schemes were essentially equal, and the separation performance of in-channel EC detection is comparable to LIF detection.     

Contactless conductivity detector for microchip capillary electrophoresis

A microfabricated electrophoresis chip with an integrated contactless conductivity detection system is described. The new contactless conductivity microchip detector is based on placing two planar sensing aluminum film electrodes on the outer side of a poly(methyl methacrylate) (PMMA) microchip (without contacting the solution) and measuring the impedance of the solution in the separation channel. The contactless route obviates problems (e.g., fouling, unwanted reactions) associated with the electrode-solution contact, offers isolation of the detection system from high separation fields, does not compromise the separation efficiency, and greatly simplifies the detector fabrication. Relevant experimental variables, such as the frequency and amplitude of the applied ac voltage or the separation voltage, were examined and optimized. The detector performance was illustrated by the separation of potassium, sodium, barium, and lithium cations and the chloride, sulfate, fluoride, acetate, and phosphate anions. The response was linear (over the 20 microM-7 mM range) and reproducible (RSD = 3.4-4.9%; n = 10), with detection limits of 2.8 and 6.4 microM (for potassium and chloride, respectively). The advantages associated with the contactless conductivity detection, along with the low cost of the integrated PMMA chip/detection system, should enhance the power and scope of microfluidic analytical devices.     

Labeling of capsid proteins and genomic RNA of human rhinovirus with two different fluorescent dyes for selective detection by capillary electrophoresis

During uncoating of human rhinoviruses, the innermost capsid protein VP4 and the genomic RNA are released from the viral protein shell. This process gives rise to subviral particles that are composed of the remaining three capsid proteins VP1, VP2, and VP3. The process is believed to take place in a sequential manner in that first VP4 is expelled resulting in A-particles sedimenting at 135S followed by the RNA resulting in B-particles sedimenting at 80S. Aiming at ultimately analyzing this process in vivo, we introduced two different fluorophores into the RNA and the viral capsid proteins, respectively. Incubation of the virus with RiboGreen resulted in formation of a RNA-dye complex with lambda(ex)/lambda(em) = 500/525 nm, whereas subsequent derivatization of the viral protein shell in the same sample with AMCA-S introduced a label with lambda(ex)/lambda(em) = 345-350/440-460 nm. In this way, both viral components could be selectively detected via fluorescence in a capillary electrophoresis system. The intact virus delivers two superimposed signals in the electropherogram. Derivatization of the free amino groups of the capsid proteins partially preserved the bioaffinity of the virus toward a synthetic receptor fragment, an artificial recombinant concatemer of repeat number 3 of the very low density lipoprotein receptor. Between 10 and 20% of the infectivity were recovered after labeling when compared to native virus. In addition to analysis of factors influencing the stability of the virus by CE, double-labeled virions might be useful for the investigation of the uncoating process by real-time confocal fluorescence microscopy.     

Dynamic labeling during capillary or microchip electrophoresis for laser-induced fluorescence detection of protein-SDS complexes without pre- or postcolumn labeling.

The analysis of proteins under denaturing conditions is routinely performed with SDS-polyacrylamide gel electrophoresis. The automated capabilities of CE, use of nongel sieving matrixes, and on-line optical detection by either ultraviolet (UV) absorption or laser-induced fluorescence (LF) promise to revolutionize this method. While direct on-line detection of proteins is possible as a result of their intrinsic ability to absorb light in the UV part of the spectrum (detection sensitivity comparable to Coomassie Blue staining of gels), LIF provides more powerful detection but requires pre- or postcolumn fluorescence labeling of the proteins. The development of a protocol analogous to that used for double-stranded DNA analysis, where fluorescent intercalating dyes are simply included in the separation medium, would simplify size-based protein analysis immensely. This would avoid the complications associated with covalent modification of the proteins but still exploit the sensitivity of LIF detection. We demonstrate that this is possible with CE and microchip detection by incorporating, into the run buffer, a fluorescent dye that interacts hydrophobically with protein-SDS complexes. Key to this is a dye that fluoresces significantly when bound to protein-SDS complexes but not when bound to SDS micelles. Comparison of electropherograms from CE-based denaturing protein analysis with UV and LIF detection indicates that the presence of the fluor does not alter separation of the proteins. Moreover, comparison with electropherograms generated from microchip electrophoresis with LIF detection shows that equivalent patterns can be obtained. Despite the unoptimized nature of this separation system, a dynamic labeling protocol that allows for LIF detection for proteins is attractive and has the potential to circumvent the tedious labeling steps typically required.     

Sheath-flow cuvette for high-sensitivity laser-induced fluorescence detection in capillary electrophoresis

The sheath-flow cuvette is a key component in a high-sensitivity post-column laser-induced fluorescence detector for capillary electrophoresis. Most designs are based on commercial cuvettes originally manufactured for use in a flow cytometer. In these devices, a quartz flow chamber is held in a stainless-steel fixture that is difficult to machine and subjects the cuvette to a torque when sealed, which frequently leads to damage of the flow chamber. In this report we present a design for a cuvette that may easily be constructed. This design uses compression to hold and seal the quartz flow chamber without applying torque. The system produces detection limits (3sigma) of 115 yoctomoles (70 copies) for FQ-labeled carbonic anhydrase.     

Biarsenical-tetracysteine motif as a fluorescent tag for detection in capillary electrophoresis

Biarsenical dyes complexed to tetracysteine motifs have proven to be highly useful fluorescent dyes in labeling specific cellular proteins for microscopic imaging. Their many advantages include membrane permeability, relatively small size, stoichiometric labeling, high affinity, and an assortment of excitation/emission wavelengths. The goal of the current study was to determine whether the biarsenical labeling scheme could be extended to fluorescent detection of analytes in capillary electrophoresis. Recombinant protein or synthesized peptides containing the optimized tetracysteine motif "-C-C-P-G-C-C-" were labeled with biarsenical dyes and then analyzed by micellar electrokinetic capillary chromatography (MEKC). The biarsenical-tetracysteine complex was stable and remained fluorescent under standard MEKC conditions for peptide and protein separations. The detection limit following electrophoresis in a capillary was less than 3 x 10(-20) mol with a simple laser-induced fluorescence system. A mixture of multiple biarsenical-labeled peptides and a protein were easily resolved. Demonstrating that the label did not interfere with bioactivity, a peptide-based enzyme substrate conjugated to the tetracysteine motif and labeled with a biarsenical dye retained its ability to be phosphorylated by the parent kinase. The feasibility of using this label for chemical cytometry experiments was shown by intracellular labeling and subsequent analysis of a recombinant protein possessing the tetracysteine motif expressed in living cells. The extension of the biarsenical-tetracysteine tag to fluorescent labeling of peptides and proteins in chemical separations is a valuable addition to biochemical and cell-based investigations.     

Three-electrode electrochemical detector and platinum film decoupler integrated with a capillary electrophoresis microchip for amperometric detection

This article demonstrates that a three-electrode electrochemical (EC) detector and an electric decoupler could be fabricated in the same glass chip and integrated with an O2-plasma-treated PDMS layer using microfabrication techniques to form the capillary electrophoresis (CE) microchip. The platinized decoupler could mostly decouple the electrochemical detection circuit from the interference of an separation electric field in 10 mM 2-(N-morpholino)ethanesulfonic acid (MES, pH 6.5) solution. The baseline offset of background current recorded from the working electrode with and without application of a separation electric field was maintained at less than 0.05 pA in 10 mM MES. In addition, the platinized pseudoreference electrode was demonstrated to offer a stable potential in electrochemical detection. As a consequence, the limit of detection of dopamine was 0.125 microM at a S/N = 4. The responses for dopamine to different concentrations were found to be linear between 0.25 and 50 microM with a correlation coefficient of 0.9974 and a sensitivity of 11.76 pA/microM. The totally integrated CE-EC microchip should be able to fulfill the ideal of miniaturization and commercialization.     

Electrochemical detection method for nonelectroactive and electroactive analytes in microchip electrophoresis

In this work, we establish an indirect amperometric detection method via mounting a single carbon fiber disk working electrode in the end part of a microchannel. This in-channel configuration for microchip capillary electrophoresis brings about that the potential of the working electrode in the case of electrochemical reduction reaction is coupled by the separation electric field, while the potential of the working electrode in the case of electrochemical oxidation reaction is not coupled by the separation electric field. Such a special performance provides a convenient and sensitive approach for indirectly detecting nonelectroactive analytes that relies on amperometric response of dissolved oxygen in solution and directly detecting electroactive analytes based on their own amperometric response on the carbon fiber electrode. This method has shown its essential importance in the analysis of inorganic cations, biomolecules, and electroosmotic flow rates. Based on preliminary results, a detection limit of 1.0 microM for K(+) and Na(+) have been achieved.     

Chemiluminescence detection for a microchip capillary electrophoresis system fabricated in poly(dimethylsiloxane)

Chemiluminescence (CL) detection integrated with a microchip capillary electrophoresis (MCE) system that was fabricated in poly(dimethylsiloxane) was demonstrated for chemical and biochemical analyses. Two model CL systems were involved here: metal ion-catalyzed luminol-peroxide reaction and dansyl species conjugated peroxalate-peroxide reaction. Different strategies based on three chip patterns (cross, cross combining with Y, and cross combining with V) to perform on-line CL detection for MCE were evaluated and compared in terms of sensitivity, reproducibility, and peak symmetry. The chip pattern of cross combining with Y proved to be promising for the luminol-peroxide CL system, while the chip pattern of cross combining with V was preferred for the peroxalate-peroxide system where CL reagent could not be effectively transported by electroosmotic flow. A detection limit down to submicromolar concentrations (midattomole) was achieved with good reproducibility and symmetric peak shape. Successful separation of three metal cations such as Cr(III), Co(II), and Cu(II) and chiral recognition of dansyl phenylalanine enantiomers within 1 min revealed distinct advantages of combining MCE with CL detection for rapid and sensitive analyses.