Poly(N-isopropylacrylamide)-g-poly(ethyleneoxide) for high resolution and high speed separation of DNA by capillary electrophoresis.

A new separation medium, poly(N-isopropylacrylamide)-g-poly(ethyleneoxide) (PNI-PAM-g-PEO) solution, used for double-stranded (ds) DNA separation by capillary electrophoresis (CE) is presented. This type of grafted copolymer has a good self-coating ability for quartz capillary tubing and a slightly temperature-dependent viscosity-adjustable property, making it easier to use. One bp resolution was achieved within 12.5 min by using 8% w/v PNIPAM-gPEO in 1 x TBE (Tris-borate-ethylenediaminetetraaceticacid) buffer with an effective column length of 10 cm and an applied electric field strength of 200 V/cm. The PNIPAM-g-PEO solutions had a high sieving ability for relatively small sized DNAs with the relative standard derivation for the first 10 runs being less than 0.9% by using the same polymer solution. With 8% w/v PNIPAM-g-PEO solution in a 1.5 cm column and 2400 V as the running voltage, phiX174/HaeIII digest could be clearly separated within 24 s.     

Concentration gradient used in double-stranded DNA separation by capillary electrophoresis

Effects of concentration gradient on double-stranded DNA (dsDNA) separation by capillary electrophoresis are presented. By using a concentration gradient in the range between 0.8% and 3.2% for poly(N,N-dimethylacrylamide) (PDMA), the presence of a mesh-size gradient in the capillary could enhance the separation of larger size DNA fragments, better than that based on a single uniform concentration over the same capillary length. A decrease in the column length could make the gradient effect more obvious. An optimal capillary length could be achieved by using a judicious combination of the concentration gradient and the concentration range, yielding a maximum resolution for the system. The standard deviation of the migration time measured for each DNA fragment was less than 5% in ten continuous runs, suggesting that the gradient formed inside the column was quite stable.     

Fast DNA sequencing up to 1,000 bases by capillary electrophoresis using poly(N,N-dimethylacrylamide) as a separation medium

Poly(N,N-dimethylacrylamide) (PDMA) with a molecular mass of 5.2 x 10(6) g/mol has been synthesized and used in DNA sequencing analysis by capillary electrophoresis (CE). A systematic investigation is presented on the effects of different separation conditions, such as injection amount, capillary inner diameter, polymer concentration, effective separation length, electric field and temperature, on the resolution. DNA sequencing up to 800 bases with a resolution (R) limit of 0.5 (and 1,000 bases with a resolution limit of 0.3) and a migration time of 96 min was achieved by using 2.5% w/v polymer, 150 V/cm separation electric field, and 60 cm effective separation length at room temperature on a DNA sample prepared with FAM-labeled--21M13 forward primer on pGEM3Zf(+) and terminated with ddCTP. Ultrafast and fast DNA sequencing up to 420 and 590 bases (R > or = 0.5) were also achieved by using 3% w/v polymer and 40 cm effective separation length with a separation electric field of 525 and 300 V/cm, and a migration time of 12.5 and 31.5 min, respectively. PDMA has low viscosity, long shelf life and dynamic coating ability to the glass surface. The unique properties of PDMA make it a very good candidate as a separation medium for large-scale DNA sequencing by capillary array electrophoresis (CAE).     

DNA sequencing of close to 1000 bases in 40 minutes by capillary electrophoresis using dimethyl sulfoxide and urea as denaturants in replaceable linear polyacrylamide solutions

The goal of this work was to reduce the capillary electrophoresis (CE) separation time of DNA sequencing fragments with linear polyacrylamide solutions while maintaining the previously achieved long read lengths of 1000 bases. Separation speed can be increased while maintaining long read lengths by reducing the separation matrix viscosity and/or raising the column temperature. As urea is a major contributor to the separation buffer viscosity, reducing its concentration is desirable both for increase in the separation speed and easier solution replacement from the capillary. However, at urea concentrations below 6 M, the denaturing capacity of the separation buffer is not sufficient for accurate base-calling. To restore the denaturing properties of the buffer, a small amount of an organic solvent was added to the formulation. We found that a mixture of 2 M urea with 5% v/w of dimethyl sulfoxide (DMSO) resulted in 975 bases being sequenced at 70 degrees C in 40 min with 98.5% accuracy. To achieve this result, the software was modified to perform base-calling at a peak resolution as low as 0.24. It is also demonstrated that the products of thermal decomposition of urea had a deleterious effect on the separation performance at temperatures above 70 degrees C. With total replacement of urea with DMSO, at a concentration of 5% v/w in the same linear polyacrylamide (LPA)-containing buffer, it was possible to increase the column temperature up to 90 degrees C. At this temperature, up to 951 bases with 98.5% accuracy could be read in only 32 min of separation. However, with DMSO alone, some groups of C-terminated peaks remained compressed, and column temperature at this level cannot at present be utilized with existing commercial instrumentation.     

Mixed triblock copolymers used as DNA separation medium in capillary electrophoresis

A polymer solution, formed by mixing two polyoxybutylene-polyoxyethylene-polyoxybutylene (BEB) triblock copolymers (B10E270B10 and B6E46B6), was tested as a new separation medium for double-stranded DNA separation in capillary electrophoresis. The mixture of B10E270B10 and B6E46B6 has a viscosity-adjustable property and a dynamic coating ability, which makes the medium very easy to handle. The performance of the mixture on the DNA separation is greatly affected by the mass ratio of the two constituents. There is a minimum amount of concentration for B10E270B10, below which the medium will lose its performance. The addition of B6E46B6 increases both the selectivity and the separation efficiency. The optimal concentration, with 3% (w/v) B10E270B10 and 5% (w/v) B6E46B6, is determined with the consideration of both speed and resolution. A resolution of 1.3 was achieved on the separation of 123/124 base pairs in the pBR322/HaeIII digest within 20 min by using a 10 cm column of 75 microm I.D., demonstrating the potential use of mixtures of amphiphilic block copolymers as an effective DNA separation medium.     

Separation of double-stranded DNA fragments by capillary electrophoresis in interpenetrating networks of polyacrylamide and polyvinylpyrrolidone

Mixtures of two polymers with totally different chemical structures, polyacrylamide and polyvinylpyrrolidone (PVP) have been successfully used for double-stranded DNA separation. By polymerization of acrylamide in a matrix of PVP solution, the incompatibility of these two polymers was suppressed. Laser light scattering (LLS) studies showed that highly entangled interpenetrating networks were formed in the solution. Further systematic investigation showed that double-stranded DNA separation was very good in these interpenetrating networks. With a concentration combination of as low as 2% w/v PVP (weight-average molecular mass Mr = 1 x 10(6) g/mol) + 1% w/v polyacrylamide (Mr = 4 x 10(5) g/mol), the 22 fragments in pBR322/HaeIII DNA, including the doublet of 123/124 bp, have been successfully separated within 6.5 min. Under the same separation conditions, similar resolution could only be achieved by using polyacrylamide (Mr = 4 x 10(5) g/mol) with concentrations higher than 6% w/v and could not be achieved by using only PVP (Mr = 1 x 10(6) g/mol) with a concentration as high as 15% w/v. It is noted that the interpenetrating network formed by 2% PVP and 1% polyacrylamide has a very low viscosity and can dynamically coat the inner wall of a fused-silica capillary. The separation reached an efficiency of more than 10(7) theoretical plate numbers/m and a reproducibility of less than 1% relative standard deviation of migration time in a total of seven runs. The interpenetrating network could stabilize polymer chain entanglements. Consequently, the separation speed was increased while retaining resolution.     

DNA sequencing with hydrophilic and hydrophobic polymers at elevated column temperatures

Read length in DNA sequencing by capillary electrophoresis at elevated temperatures is shown to be greatly affected by the extent of hydrophobicity of the polymer separation matrix. At column temperatures of up to 80 degrees C, hydrophilic linear polyacrylamide (LPA) provides superior read length and separation speed compared to poly(N,N-dimethylacrylamide) (PDMA) and a 70:30 copolymer of N,N-dimethylacrylamide and N,N-diethylacrylamide (PDEA30). DNA-polymer and polymer intramolecular interactions are presumed to be a major cause of band broadening and the subsequent loss of separation efficiency with the more hydrophobic polymers at higher column temperatures. With LPA, these interactions were reduced, and a read length of 1000 bases at an optimum temperature of 70 degrees -75 degrees C was achieved in less than 59 min. By comparison, PDMA produced a read length of roughly 800 bases at 50 degrees C, which was close to the read length attained in LPA at the same temperature; however, the migration time was approximately 20% longer, mainly because of the higher polymer concentration required. At 60 degrees C, the maximum read length was 850 bases for PDMA, while at higher temperatures, read lengths for this polymer were substantially lower. With the copolymer DEA30, read length was 650 bases at the optimum temperature of 50 degrees C. Molecular masses of these polymers were determined by tandem gel permeation chromatography-multiangle laser light scattering method (GPC-MALLS). The results indicate that for long read, rapid DNA sequencing and analysis, hydrophilic polymers such as LPA provide the best overall performance.     

Clay-enhanced DNA separation in low-molecular-weight poly(N,N-dimethylacrylamide) solution by capillary electrophoresis

The effect of the separation medium in capillary electrophoresis consisting of a low-molecular-mass poly(N,N-dimethylacrylamide) (PDMA) solution on the DNA separation by adding a small amount of montmorillonite clay into the polymer matrix is presented. On the separation of the pBR322/HaeIII digest, both the resolution and the efficiency were increased by adding 2.5-5.0 x 10(-5) g/mL clay into the 5% w/v PDMA with a molecular mass of only 100 K. Moreover, there was no increase in the migration time of DNA fragments. Similar results were observed by using a C-terminated pGEM-3Zf(+) sequencing DNA sample in a sequencing buffer. Experimental data also showed that the addition of clay increased the viscosity of the polymer solution. We attribute this effect to the structural change of the polymer matrix caused by the exfoliated clay sheets, whereby the thin clay sheets function like a "dynamic cross-linking plate" for the PDMA chains and effectively increase the apparent molecular mass of PDMA.     

Impact of polymer hydrophobicity on the properties and performance of DNA sequencing matrices for capillary electrophoresis

To elucidate the impact of matrix chemical and physical properties on DNA sequencing separations by capillary electrophoresis (CE), we have synthesized, characterized and tested a controlled set of different polymer formulations for this application. Homopolymers of acrylamide and N,N-dimethylacrylamide (DMA) and copolymers of DMA and N,N-diethylacrylamide (DEA) were synthesized by free radical polymerization and purified. Polymer molar mass distributions were characterized by tandem gel permeation chromatography - laser light scattering. Polymers with different chemical compositions and similar molar mass distributions were selected and employed at the same concentration so that the variables of comparison between them were hydrophobicity and average coil size in aqueous solution. We find that the low-shear viscosities of 7% w/v polymer solutions decrease by orders of magnitude with increasing polymer hydrophobicity, while hydrophilic polymers exhibit more pronounced reductions in viscosity with increased shear. The performance of the different matrices for DNA sequencing was compared with the same sample under identical CE conditions. The longest read length was produced with linear polyacrylamide (LPA) while linear poly-N,N-dimethylacrylamide (PDMA) gave approximately 100 fewer readable bases. Read lengths with DMA/DEA copolymers were lower, and decreased with increasing DEA content. This study highlights the importance of polymer hydrophilicity for high-performance DNA sequencing matrices, through the formation of robust, highly-entangled polymer networks and the minimization of hydrophobic interactions between polymers and fluorescently-labeled DNA molecules. However, the results also show that more hydrophobic matrices offer much lower viscosities, enabling easier microchannel loading at low applied pressures.     

DNA sequencing by capillary electrophoresis using mixtures of polyacrylamide and poly(N,N-dimethylacrylamide)

The possibility of using polymer mixtures with different chemical compositions as a DNA sequencing matrix by capillary electrophoresis (CE) has been exploited. Polyacrylamide (PAM, 2.5%, w/v) having a molecular mass of 2.2 x 10(6) has been mixed with poly(N,N-dimethylacrylamide) (PDMA) having molecular masses of 8000, 470000 and 2.1 x 10(6) at concentrations of 0.2, 0.5 and 1% (w/v). Unlike polymer mixtures of the same polymer with different molecular masses, the use of polymer mixtures with different chemical compositions encounters an incompatibility problem. It was found that the incompatibility increased with increasing PDMA molecular mass and PDMA concentration, which resulted in decreased efficiency in DNA sequencing. Also, the incompatibility had a more pronounced effect on the efficiency as the base number was increased. However, by choosing a low-molecular-mass PDMA of 8000 and a low concentration of 0.2% (w/v), the incompatibility of PAM and PDMA has been alleviated. At the same time, the advantage of using polymer mixtures revealed a higher efficiency for such a polymer mixture when compared with PAM. The mixture also endowed the separation medium with a dynamic coating ability. An efficiency of over 10 x 10(6) theoretical plates per meter has been achieved by using the bare capillaries without the additional chemical coating step.     

DNA sequencing by capillary electrophoresis using copolymers of acrylamide and N,N-dimethylacrylamide

Copolymers of acrylamide (AM) and N,N-dimethylacrylamide (DMA) with AM to DMA molar ratios of 3:1, 2:1 and 1:1 and molecular weights of about 2.2 MDa were synthesized. The polymers were tested as separation media in DNA sequencing analysis by capillary electrophoresis (CE). The dynamic coating ability of polydimethylacrylamide (PDMA) and the hydrophilicity of polyacrylamide (PAM) have been successfully combined in these random copolymers. A separation efficiency of over 10 million theoretical plates per meter has been reached by using the bare capillaries without the additional polymer coating step. Under optimized separation conditions for longer read length DNA sequencing, the separation ability of the copolymers decreased with decreasing AM to DMA molar ratio from 3:1, 2:1 and 1:1. In comparison with PAM, the copolymer with a 3:1 AM:DMA ratio showed a higher separation efficiency. By using a 2.5% w/v copolymer with 3:1 AM:DMA ratio, one base resolution of 0.55 up to 699 bases and 0.30 up to 963 bases have been achieved in about 80 min at ambient temperatures.     

A novel thermogelling matrix for microchannel DNA sequencing based on poly-N-alkoxyalkylacrylamide copolymers

We have developed a novel class of thermogelling polymer networks based on poly-N-alkoxyalkylacrylamides, and demonstrated their use as DNA sequencing matrices for high-throughput microchannel electrophoresis in capillary arrays. Polymers and copolymers of N-ethoxyethylacrylamide (NEEA) and N-methoxyethylacrylamide (NMEA) were synthesized by aqueous-phase free-radical polymerization and characterized by tandem gel permeation chromatography-multi-angle laser light scattering. These copolymer matrices exhibit "re-entrant"-type volume phase transitions, forming entangled networks with high shear viscosity at low (< 20 degrees C) and high (> 35 degrees C) temperatures, and undergoing a "coil-to-globular", lower critical solution temperature (LCST)-like phase transition over an intermediate temperature range (20-35 degrees C). Hence, matrix viscosity is relatively low at room temperature (25 degrees C), and increases rapidly above 35 degrees C. The material properties and phase behavior of these thermogelling polymer networks were studied by steady-shear rheometry. These matrices are easily loaded into capillary arrays at room temperature while existing as viscous fluids, but thermogel above 35 degrees C to form transparent hydrogels via a thermo-associative phase transition. The extent of the intermediate viscosity drop and the final viscosity increase depends on the composition of the copolymers. DNA sequencing by capillary array electrophoresis with four-color laser-induced fluorescence (LIF) detection shows that these thermogelling networks provide enhanced resolution of both small and large DNA sequencing fragments and longer sequencing read lengths, in comparison to appropriate control (closely related, nonthermogelling) polymer networks. In particular, a copolymer comprised of 90% w/w NMEA and 10% w/w NEEA, with a molecular mass of approximately 2 MDa, delivers around 600 bases at 98.5% base-calling accuracy in 100 min of electrophoresis.     

A theoretical study of the possible use of electroosmotic flow to extend the read length of DNA sequencing by end-labeled free solution electrophoresis

End-labeled free solution electrophoresis (ELFSE) provides a means of separating DNA with free-solution CE, eliminating the need for gels and polymer solutions which increase the run time and can be difficult to load into a capillary. In free-solution electrophoresis, DNA is normally free-draining and all fragments reach the detector at the same time, whereas ELFSE uses an uncharged label molecule attached to each DNA fragment in order to render the electrophoretic mobility size-dependent. With ELFSE, however, the larger molecules are not separated enough (limiting the read length in the case of ssDNA sequencing) while the smaller ones are overseparated; the larger ones are too fast while the shorter ones are too slow, which is the opposite of traditional gel-based methods. In this article, we show how an EOF could be used to overcome these problems and extend the DNA sequencing read length of ELFSE. This counterflow would allow the larger, previously unresolved molecules more time to separate and thereby increase the read length. Through our theoretical investigation, we predict that an EOF mobility of approximately the same magnitude as that of unlabeled DNA would provide the best results for the regime where all molecules move in the same direction. Even better resolution would be possible for smaller values of EOF which allow different directions of migration; however, the migration times then would become too large. The flow would need to be well controlled since the gain in read length decreases as the magnitude of the counterflow increases; an EOF mobility double that of unlabeled DNA would no longer increase the read length, although ELFSE would still benefit from a reduction in migration time.     

Fast separation of single-stranded oligonucleotides by capillary electrophoresis using OliGreen as fluorescence inducing agent

The fast separation of oligonucleotide (oligos) sizing marker by CE using OliGreen and including effects due to the concentration of separation medium and urea denaturant is presented. OliGreen dye is found to be more sensitive than ethidium bromide (by a factor of about 6 based on S/N considerations) for the oligos' separations. Higher concentration of F127 in 1xTris-boricacid-EDTA (TBE) up to 30% w/v leads to better resolution of oligos separations. The addition of urea into the separation medium decreases the sensitivity. With an optimized running condition, the oligos sizing marker could be successfully separated with 1-base resolution within 1.3 min by using 30% w/v F127/1xTBE solution as the separation medium at an applied electric field of 800 V/cm in a 3 cm long capillary, the fastest capillary gel electrophoresis separation with high resolution reported to date for oligos in the similar size range.     

Capillary zone electrophoresis of rigid submicron-sized particles in polyacrylamide. Solution selectivity, peak spreading and resolution.

Submicron-sized rigid particles can be separated in a size-dependent fashion by electrophoresis in free solution. Yet it has remained unknown whether the presence of polymers in the solution confers an advantage in size-dependent separation of submicron particles and their resolution. The present study addresses that question, using capillary zone electrophoresis of carboxylate modified polystyrene latex microspheres of 55, 140 and 215 nm radius in solutions of linear polyacrylamide in the M(r) range of 0.4.10(6) to 1.14.10(6). Selectivity of particle separation increases in direct relation to the polymer concentration in the concentration range of 0 to 1% (w/v). Selectivity was found to increase with M(r) of the polymer for the particle sets of 55/140 (nm/nm) and 140/215 (nm/nm) but to decrease with polymer M(r) for the 55/215 (nm/nm) set. Peak spreading is a complex and, in the case of the largest particle, non-monotonic function of polymer concentration, with a minimum at concentrations around the entanglement threshold, c*. Consequently, resolution of the 55/215 and 140/215 (nm/nm) sets also exhibits a maximum around the entanglement threshold while resolution for the 55/140 (nm/nm) set increases with a rise of polymer concentrations above c*. Within the range of optimally resolving polymer concentrations there also occurs a maximum of resolution for all particle sets at a field strength in the range of 150 to 250 V cm-1.     

Stepwise gradient of linear polymer matrices in microchip electrophoresis for high-resolution separation of DNA

The stepwise gradient of linear polymer matrices in microchannel electrophoresis is proposed as a means of achieving high-resolution separation of DNA samples containing a wide range of fragment sizes. In this method, multiple discrete steps in terms of polymer type or concentration are created in the microchannel by injecting appropriate solutions in order. The mixing of the various steps is found to be negligible compared to the effective length of separation channel, confirming that a stepwise gradient of matrices is formed. This technique is successfully applied to the analysis of restriction digest fragments and DNA ladders, and is demonstrated to provide higher resolution than the isocratic method, for both small and large fragments simultaneously. Even though the stepwise gradient is created manually, the reproducibility of the migration times of fragments in DNA samples is found to be quite good. Taken the separation of 100 bp DNA ladder in three steps gradient pattern as an example, the relative standard deviations of migration times are respectively less than 0.53% and 3.1% in six consecutive injections in one channel and in different channels. The migration of DNA fragments in gradient mode is shown to be similar to that for the isocratic scheme, allowing the design of each step to be made in reference to existing knowledge. These promising results indicate the great potential of this stepwise gradient method for the analysis of DNA by microchip electrophoresis, offering both high resolution and good reproducibility.     

Pressurized gradient capillary electrochromatographic separation of eighteen amino acid derivatives

A pressurized gradient capillary electrochromatography (pCEC) instrument was developed to separate 18 amino acid derivatives. A reversed-phase C18 column (3 microm, 130 mm x 75 microm I.D.) and an acetate buffer (50 mmol/l NaAc, pH 6.4) with an ion-pair reagent (1% N,N-dimethylformamide) were used to separate derivatized amino acids from a standard solution (2 microg/ml), and the wavelength of the UV-Vis detector was 360 nm. The pressure on the capillary column was kept at approx. 70 Pa and 3 kV positive voltage was added on the outlet end of column. The effect of voltage on the eluting order of amino acids and the resolution of separation were studied, and it was found that when the voltage was higher than 3 kV, the adsorption of amino acids in the porous C18 column occurred. The effect of salt concentration, injection volume, and column length on the separation of amino acids was determined. The amino acid sample was separated by pCEC, and RSDs of the migration times of each amino acid were all less than 2.5%.     

Theoretical background of short chromatographic layers. Optimization of gradient elution in short columns

Although linear salt gradient elution ion-exchange chromatography (IEC) of proteins is commonly carried out with relatively short columns, it is still not clear how the column length affects the separation performance and the economics of the process. The separation performance can be adjusted by changing a combination of the column length, the gradient slope and the flow velocity. The same resolution can be obtained with a given column length with different combinations of the gradient slope and the flow velocity. This results in different separation time and elution volume at the same resolution. Based on our previous model, a method for determining the separation time and the elution volume relationship for the same resolution (iso-resolution curve) was developed. The effect of the column length and the mass transfer rate on the iso-resolution curve was examined. A long column and/or high mass transfer rate results in lesser elution volume. The resolution data with porous bead packed columns and monolithic columns were in good agreement with the calculated iso-resolution curves. Although the elution volume can be reduced with increasing column length, the pressure drop limits govern the optimum conditions.     

Chiral separation of β‐blockers by MEEKC using neutral microemulsion: Analysis of separation mechanism and further elucidation of resolution equation

Based on the investigation of the effect of microemulsion charge on the chiral separation, a new chiral separation method with MEEKC employing neutral microemulsion was established. The method used a microemulsion containing 3.0% (w/v) neutral surfactant Tween 20 and 0.8% (w/v, 30 mM) dibutyl l ‐tartrate in 40 mM sodium tetraborate buffer to separate the enantiomers of β‐blockers. The effect of major parameters on the chiral separation was investigated. The applied voltage had little effect on the resolution, but the chiral separation could be improved by suppressing the EOF. Nine racemic β‐blockers obtained relatively good enantioseparation after appropriate concentrations of tetradecyl trimethyl ammonium bromide were added into the microemulsion to suppress the EOF. These results were explained based on the analysis of the separation mechanism of the method and deduced separation equations. The resolution equation of the method was further elucidated. It was found that the fourth term in the resolution equation, an additional term compared to the conventional resolution equation for column chromatography, represents the ratio of the relative movement distance between the analyte and microemulsion droplets relative to the effective capillary length. It can be regarded as a correction for the effective capillary length. These findings are significant for the development of the theory of MEEKC and the development of new chiral MEEKC method.     

Separation of structurally related estrogens using isocratic elution pressurized capillary electrochromatography

In this paper, the pressurized capillary electrochromatography (pCEC) with UV detection was utilized for the separation and determination of three structurally related estrogens, such as diethylstilbestrol (DES), hexestrol (HEX) and dienestrol (DE), which were difficult to be separated by capillary electrophoresis (CE) and HPLC due to their similarity in the structure and charge-to-mass ratios. Experiments were carried out in a commercially available pCEC instrument using a capillary column packed with 3 microm octadecyl silica (ODS). Surfactant sodium dodecyl sulfate (SDS) was introduced in the mobile phase to enhance the speed of analysis. The effective factors on the retention time and separation resolution, such as the applied voltage, supplementary pressure, the pH and the concentration of the buffer solution, the concentration of SDS, and the content of acetonitrile in the mobile phase, were evaluated. Based on the investigation, 31% (v/v) acetonitrile and 69% (v/v) of 10 mmol/L phosphate buffer (pH 6.5) containing 1.0 mmol/L SDS at an applied voltage of -12 kV and a supplementary pressure of 1000 psi were found to be the optimal conditions for pCEC to separate the three estrogens. The method also had been applied to the analysis of fish muscle samples spiked with estrogens.