A continuous-flow,microfluidic fraction collection device

A microfluidic device is presented that performs electrophoretic separation coupled with fraction collection. Effluent from the 3.5 cm separation channel was focused via two sheath flow channels into one of seven collection channels. By holding the collection channels at ground potential and varying the voltage ratio at the two sheath flow channels, the separation effluent was directed to either specific collection channels, or could be swept past all channels in a defined time period. As the sum of the voltages applied to the two sheath flow channels was constant, the electric field remained at 275 V/cm during the separation regardless of the collection channel used. The constant potential in the separation channel allowed uninterrupted separation for late-migrating peaks while early-migrating peaks were being collected. To minimize the potential for carryover between fractions, the device geometry was optimized using a three-level factorial model. The optimum conditions were a 22.5° angle between the sheath flow channels and the separation channel, and a 350 μm length of channel between the separation outlet and the fraction channels. Using these optimized dimensions, the device performance was evaluated by separation and fraction collection of a fluorescently labeled amino acid mixture. The ability to fraction collect on a microfluidic platform will be especially useful during automated or continuous operation of these devices or to collect precious samples.     

Miniaturization of capillary isoelectric focusing.

Miniaturization of whole-column imaging capillary isoelectric focusing (CIEF) is discussed. A 1.2 cm capillary was used as a separation column for CIEF. The experimental results for the analysis of two pI markers and the protein myoglobin showed that good CIEF separation results could be obtained. Secondly, a light-emitting diode (LED) was used as the light source for the whole-column absorbance imaging detection. The focusing of both the pI markers and myoglobin were observed with the LED light source. The whole-column imaging CIEF instrument was simplified and miniaturized by the use of the LED. Further developments are also discussed.     

The transitional isoelectric focusing process

The transitional isoelectric focusing (IEF) process (the course of pH gradient formation by carrier ampholytes (CAs) and the correlation of the focusing time with CA concentration) were investigated using a whole-column detection capillary isoelectric focusing (CIEF) system. The transitional double-peak phenomenon in IEF was explained as a result of migration of protons from the anodic end and hydroxyl ions from the cathodic end into the separation channel and the higher electric field at both acidic and basic sides of the separation channel. It was observed that focusing times increase logarithmically with CA concentration under a constant applied voltage. The correlation of focusing time with CA concentration was explained by the dependence of the charge-transfer rate on the amount of charged CAs within the separation channel during focusing.     

A multichannel gel electrophoresis and continuous fraction collection apparatus for high‐throughput protein separation and characterization

To facilitate a direct interface between protein separation by PAGE and protein identification by mass spectrometry, we developed a multichannel system that continuously collects fractions as protein bands migrate off the bottom of gel electrophoresis columns. The device was constructed using several short linear gel columns, each of a different percent acrylamide, to achieve a separation power similar to that of a long gradient gel. A “Counter Free‐Flow” elution technique then allows continuous and simultaneous fraction collection from multiple channels at low cost. We demonstrate that rapid, high‐resolution separation of a complex protein mixture can be achieved on this system using SDS‐PAGE. In a 2.5 h electrophoresis run, for example, each sample was separated and eluted into 48–96 fractions over a mass range of ～10–150 kDa; sample recovery rates were 50% or higher; each channel was loaded with up to 0.3 mg of protein in 0.4 mL; and a purified band was eluted in two to three fractions (200 μL/fraction). Similar results were obtained when running native gel electrophoresis, but protein aggregation limited the loading capacity to about 50 μg per channel and reduced resolution.     

Selective extraction of size-fractioned DNA samples in microfabricated electrophoresis devices

We have designed and constructed a microfabricated device for separation of double-stranded DNA fragments using a crosslinked sieving medium and spatially selective extraction of the desired fraction. Based on measuring the width and spacing of migrating bands, a narrow side channel is constructed perpendicular to the separation channel to collect the DNA fragments of interest. This selective collection technique was tested using a 100 base pair double-stranded DNA ladder. We successfully demonstrate selective extraction of the desired fragment with minimal interference from the adjacent bands in an electric field of 31 V/cm. We also achieve extraction of multiple DNA fragments using an array of microelectrodes in this side channel. The device uses cross-linked polyacrylamide gel matrix, allowing the separation to be performed in a distance of 1 cm or less and at a low electric field strength. Together with on-chip electrode, this design is amenable to integration with reaction chambers into a single device for portable genetic-based analysis.     

Whole-column fluorescence-imaged capillary electrophoresis

An axially illuminating whole-column fluorescence imaging capillary electrophoresis (CE) experimental setup was developed. A 6 cm long Teflon tube with an inside diameter (ID) of 42 microm was used as separation column. Excitation light of 488 nm from Ar+ laser was introduced to one end of the separation column by an optical fiber. The excitation light propagated inside the separation column by total internal reflection, since the refractive index of the buffer solution was larger than that of the Teflon tube. The fluorescence from the whole separation column was imaged with a charge-coupled device (CCD) camera. Fluorescent compounds such as fluorescein isothiocyanate (FITC), 5-carboxyfluorescein, and FITC-labeled protein were used to test the basic performance of the experimental setup. Experimental results illustrate that the whole-column-fluorescence imaging CE is a fast and sensitive separation method for fluorescent compounds and fluorescent-labeled proteins. Furthermore, it could be used for simple, fast, and easy comparisons of the resistance to photodegradation for various fluorescent compounds.     

Micromachined capillary cross-connector for high-precision fraction collection

A new approach for high-precision fraction collection of double-stranded DNA fragments by capillary electrophoresis coupled to a micromachined plastic capillary cross-connector is presented. The system design integrates four fused-silica capillaries with an acrylic cross-channel connector. The cross-channel structure was introduced to enhance the efficiency of the fraction collection process by electrokinetic manipulations. Following the detection of the sample zone of interest at or slightly upstream of the cross during the separation mode, the potentials were reconfigured to collection mode to direct the selected analyte zone into the corresponding collection vial, while keeping the rest of the sample components virtually stopped within the separation capillary. In this way the spacing between consecutive bands of interest can be physically increased, allowing precise isolation of spatially close sample zones. After collection of the target fraction the separation mode is resumed, and the separation/collection cycle is repeated until all desired sample zones are separated and captured. The capillary cross-connector was fabricated of a transparent acrylic substrate by microdrilling flat end and through channels, matching precisely the O.D. and I.D. of the connected capillary tubing, respectively. This design provided a close to zero dead volume connection assembly for the separation and collection capillaries causing minimal extra band broadening during high-precision micropreparative DNA fractionation.     

A simultaneous space sampling method for DNA fraction collection using a comb structure in microfluidic devices

Fraction collection of selected components from a complex mixture plays a critical role in biomedical research, environmental analysis, and biotechnology. Here, we introduce a novel electrophoretic chip device based on a signal processing theorem that allows simultaneous space sampling for fractionation of ssDNA target fragments. Ten parallel extraction channels, which covered 1.5-mm-long sampling ranges, were used to facilitate the capturing of fast-moving fragments. Furthermore, the space sampling extraction made it possible to acquire pure collection, even from partly overlapping fragments that had been insufficiently separated after a short electrophoretic run. Fragments of 180, 181, and 182 bases were simultaneously collected, and then the recovered DNA was PCR amplified and assessed by CE analysis. The 181-base target was shown to be isolated in a 70-mm-long separation length within 10 min, in contrast to the >50 min required for the 300-mm-long separation channel in our previous study. This method provides effective combination of time and space, which is a breakthrough in the traditional concept of fraction collection on a chip.     

Design of a fraction collector for capillary array electrophoresis

This paper describes a prototype instrument for high-throughput fraction collection with capillary array electrophoresis (CAE). The design of the system was based on a comprehensive collection approach, in which fractions from all capillaries were simultaneously collected in individual collection microwells in predefined time intervals. The location of the fractions in the microwells on the collection plate was determined by monitoring the individual zone velocities close to the end of each capillary. The collection microwell plate was fabricated from buffer-saturated agarose gel, which maintained permanent electrical contact with the separation capillaries during the collection process. Since the collection gel plate consisted of over 90% water, liquid evaporation from the collection wells was minimized. A 12-capillary array instrument was built with two-point detection using a side illumination scheme. The collection performance was demonstrated by reinjection of selected fractions of a double-stranded DNA (dsDNA) separation. The identity of collected DNA fragments was confirmed by PCR and sequencing.     

Pressure-driven sample injection with quantitative liquid dispensing for on-chip electrophoresis.

A novel pressure-driven sample injection method was developed as an alternative to electrokinetic injection, and electrophoretic separation was carried out on a microfabricated device employing this method. This method enables a defined volume of liquid dispensing, followed by instantaneous injection driven by pneumatic pressure, greatly simplifying the injection procedure. A particular microstructure, called a "metering chamber", has been designed for the quantitative dispensing of an ultra-low volume of sample liquid; a "hydrophobic passive valve" equipped with an air vent channel is employed for injecting a dispensed sample into the separation channel. The reproducibility of dispensing was 3.3% (n = 15), expressed by the variation of dispensed volumes. The electrophoretic separation of DNA fragments was performed using this injection method, varying the injection volumes from 0.45 to 4.0 nL, and the separation efficiencies were compared. This precise injection method, easily variable in injection volumes, is highly suitable for quantitative as well as qualitative electrophoretic analyses.     

Continuous particle separation in a microchannel having asymmetrically arranged multiple branches

A new method for continuous size separation and collection of particles in microfabricated devices, asymmetric pinched flow fractionation (AsPFF), has been proposed and demonstrated. This method improves the separation scheme of pinched flow fractionation (PFF), which utilizes a laminar flow profile inside a microchannel. In this study, multiple branch channels with different channel dimensions were arranged at the end of the pinched segment, so that the flow rate distributions to each branch channel were varied, and a large part of the liquid was forced to go through one branch channel (drain channel). In the proposed channel system, the flow profile inside the microchannel was asymmetrically amplified, enabling the separation of one-order smaller particles compared with PFF. After introducing the method, we examined the effect of the asymmetric amplification by controlling the outlet of the drain channel. Also, a mixture of 1.0 approximately 5.0 microm particles was separated, and erythrocytes were successfully separated from blood. The results indicate that the AsPFF method could be applied to the separation of much smaller-size particles, since more precise separation can be achieved simply by changing the geometries of branch channels.     

On-chip fraction collection for multiple selected ssDNA fragments using isolated extraction channels

High efficiency and high-purity fraction collection is highly sought in analysis of fragments-of-interest from selective polymerase chain reaction (PCR) products generated by High Coverage Gene Expression Profiling (HiCEP) methods. Here we demonstrate a new electrophoretic chip device enabling automatic high-efficient fractionation of multiple ssDNA target fragments during a run of separation. We used thoroughly isolated extraction channels for each selected target to reduce the risk of cross-contamination between targets due to cross-talk of extraction channels. Fragments of 35, 108 and 138 b, were successfully isolated, then the recovery was PCR-amplified and assessed by capillary electrophoresis (CE) analysis. Total impurity level of the targets due to unwanted fragments of 0.7%, 2% and 6% respectively, was estimated. Difficulties in collecting multiple target factions are due to band diffusion and DNA adsorption to the walls for the fragments in the separation channel, which is generated by transferring the DNA target fraction from the extraction section to the target reservoir. Therefore, we have carefully measured band broadening and analyzed its influence on the separation resolution due to the delay.     

Fraction collection in micropreparative capillary zone electrophoresis and capillary isoelectric focusing

A new fraction collection system for capillary zone electrophoresis (CZE) and capillary isolelectric focusing (CIEF) is described. Exact timing of the collector steps was based on determining the velocity of each individual zone measured between two detection points close to the end of the capillary. Determination of the zone velocity shortly before collection overcame the need for constant analyte velocity throughout the column. Consequently, sample stacking in CZE with large injection volumes as well as zone focusing in CIEF could be utilized with high collection accuracy. Capillaries of 200 microm inner diameter (ID) were employed in CZE and 100 microm ID in CIEF for the micropreparative mode. A sheath flow fraction collector was used to maintain permanent electric current during the collection. The bulk liquid flow due to siphoning, as well as the backflow arising from the sheath flow droplet pressure, were suppressed by closing the separation system at the inlet with a semipermeable membrane. In the CZE mode, the performance of the fraction collector is demonstrated by isolation of individual peaks from a fluorescently derivatized oligosaccharide ladder. In the CIEF mode, collection of several proteins from a mixture of standards is shown, followed by subsequent analysis of each protein fraction by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS).     

Automation of radiochemical analysis by flow injection techniques: Am-Pu separation using TRU-resin™ sorbent extraction column

A rapid automated flow injection analysis (FIA) procedure was developed for efficient separation of Am and Pu from each other and from interfering matrix and radionuclide components using a TRU-resin^™column. Selective Pu elution is enabled via on-column reduction. The separation was developed using on-line radioactivity detection. After the separation had been developed, fraction collection was used to obtain the separated fractions. In this manner, a FIA instrument functions as an automated separation workstation capable of unattended operation.     

A Low-Resolution Separation of C14 -Glyburide and Its Metabolites from Plasma Extracts Using a High-Performance Liquid Chromatograph Guard Column

Abstract

A low-resolution method for simultaneous, rapid determination of radiolabeled glyburide and its metabolites in human plasma is described. Plasma samples were extracted with ethyl acetate. Extracts were redissolved in 300 μl of mobile phase, and injected into a 3 cm guard column, which was incorporated as a loop in a six-port switching valve. C¹⁴-glyburide was collected as a single 4-min fraction at a flow rate of 4 ml per min.

Following collection of a 1-ml fraction, the column was backflushed with methanol to allow collection of the metabolites of glyburide. The mean value of recovered radioactivity was 95.5 ± 5.7%. The validity of the separation was verified in a high-resolution HPLC system and no cross contamination of the fractions was observed.     

Peptide separation and isolation with an automated amino acid analyzer

A technique is presented for separation and collection of amino acids and peptides using a microcolumn amino acid analyzer. By use of the program and the column selection valve of the amino acid analyzer, and without any modification of the instrumentation, the stream of the eluate is diverted into the reaction coil and absorbance is recorded at regular intervals. The rest of the eluate is collected in a fraction collector for further characterization of the separated peptides. Splitting ratios can be varied by simple alteration of the program. Small amounts of material (1 to 2 nmol) are needed for monitoring the separation and collection of the eluate.     

Experimental Van Deemter plots of shear-driven liquid chromatographic separations in disposable microchannels

We present a new stationary phase coating method, yielding a monolayer of densely arrayed porous HPLC beads (d(p)=4 microm) for use in a disposable shear-driven flow LC system. The system is inherently suited for whole-column detection through the small voids between the individual particles of the layer. The chromatographic performance of the system has been characterized by performing a series of coumarin dye separation experiments (reversed-phase mode) and by measuring the theoretical plate height as a function of the mobile phase velocity. The resulting Van Deemter curve, yielding a value of about 90,000 plates/m near the u=u(opt) velocity, shows good agreement with the theoretical expectations, and hence constitutes the first full validation of the theory of shear-driven chromatography.     

Isolation of compounds from complex sample mixtures for identification purposes — The semi-preparative separation of natural products

Summary Semi-preparative separation and collection of compounds from complex mixtures by HPLC followed by identification of the isolated substances is a method combination which finds increasing interest in analytical laboratories. An analytical high-pressure liquid chromatograph has been enhanced with hardware that allows automatic, unattended, semi-preparative separation and fraction collection. The system is described and its practical applicability is demonstrated with the isolation of compounds from a natural product. Identification of collected sample was carried out using CI-MS, EI-MS, UV and NMR. The results show that the off-line combination of HPLC with other analytical techniques is a very powerful tool for identification purposes.     

Whole-column imaging capillary electrophoresis of proteins with a short capillary

Whole-column imaging capillary electrophoresis with a short capillary is discussed. A short capillary (3-6 cm) coated with either fluorocarbon or polyacrylamide was used as a separation capillary. The whole capillary was illuminated with 280 nm light, and the transmitted light was monitored by a linear charge-coupled device (CCD). For the short capillary, hydrodynamic flow caused by a subtle height difference between the anodic and cathodic reservoirs affected the sample migration in the capillary greatly. Several sample injection methods, including use of a cross connection, sealing of the capillary ends with a gel, and use of a gel-filled capillary, have been discussed. The experimental results showed that the peak height decreased and peak width increased with the electromigration distance. Therefore, higher sensitivity was obtained in a short capillary rather than a long capillary. The whole-column imaging CE with the short capillary has been applied for the study of conjugation reactions of protein cytochrome c with sodium dodecyl sulfate (SDS) and the dye Congo Red. The method has also been used for in situ monitoring of the electrophoretic protein desorption process. Our technique is a unique tool for the study of protein binding reactions and the interaction between analyte and inner wall of the capillary.