A low-makeup beveled tip capillary electrophoresis /electrospray ionization mass spectrometry interface for micellar electrokinetic chromatography and nonvolatile buffer capillary electrophoresis

A robust interface has been developed for interfacing micellar electrokinetic chromatography (MEKC) and nonvolatile buffer capillary electrophoresis (CE) to electrospray ionization mass spectrometry (ESI-MS). The interface consists of two parallel capillaries for separation (50 microm i.d. x 155 microm o.d.) and makeup (50 microm i.d. x 155 microm o.d.) housed within a larger capillary (530 microm i.d. x 690 microm o.d.). The capillaries terminate in a single tapered tip having a beveled edge. The use of a tapered beveled edge results in a greater tip orifice diameter (75 microm) than in a previous design from our laboratory (25 microm) that used a flat tip. While maintaining a similar optimum flow rate and consequently similar sample dilution, a 75-microm beveled emitter is more rugged than a 25-microm flat tip. Furthermore, the incorporation of a sheath liquid capillary allows the compositions of the final spray solution to be controlled. The application of this novel CE/ESI-MS interface was demonstrated for MEKC using mixtures of triazines (positive ion mode) and phenols (negative ion mode). The ability to perform CE/ESI-MS using a nonvolatile buffer was demonstrated by the analysis of gangliosides with a buffer consisting of 40 mM borate and 20 mM alpha-cyclodextrin.     

Characterization of a capillary zone electrophoresis/electrospray-mass spectrometry interface

A dependable and stable CZE/ESI-MS interface has been constructed. To avoid instabilities in both, the capillary electrophoretic separation and the electrospray, the second of the three concentric capillaries in the three-layered sprayer has been replaced by an aluminum-coated fused-silica capillary with an inner diameter only slightly greater than the outer diameter of the separation capillary. By this means, the otherwise often observed destruction of the separation capillary ("electrodrilling") can be avoided completely due to the suppression of electrochemical processes leading to gas bubble formation at the tip of the sprayer. With some examples taken from different biochemical areas and by separation of natural compounds, the capability and the reliability of the modified sprayer as the central part of the interface are demonstrated.     

Separation of nonionic surfactants by capillary electrophoresis and high-performance liquid chromatography

Fatty alcohol ethoxylates (FAEs) are applied in commercial formulations (laundry detergents) as complex mixtures of alkyl and ethoxylate homologues. Therefore, efficient analytical methods are required for product control. Capillary electrophoresis, a modern analytical separation technique, was used to separate FAEs in technical products and household formulations after derivatization with phthalic anhydride. The well-established high-performance liquid chromatography was used as reference and supplementary method. UV detection after derivatization with phenyl isocyanate or light scattering detection has been carried out. Sample components have been identified by standard addition or by comparison to known products. The peak pattern can be considered as a "fingerprint" of the product and is characteristic for a defined composition.     

On-line hyphenation of capillary isoelectric focusing and capillary gel electrophoresis by a dialysis interface

An on-line two-dimensional (2D) capillary electrophoresis (CE) system consisting of capillary isoelectric focusing (CIEF) and capillary gel electrophoresis (CGE) was introduced. To validate this 2D system, a dialysis interface was developed by mounting a hollow fiber on a methacrylate resin plate to hyphenate the two CE modes. The two dimensions of capillary shared a cathode fixated into a reservoir in the methacrylate plate; thus, with three electrodes and only one high-voltage source, a 2D CE framework was successfully established. A practical 2D CIEF-CGE experiment was carried out to deal with a target protein, hemoglobin (Hb). After the Hb variants with different isoelectric points (pIs) were focused in various bands in the first-dimension capillary, they were chemically mobilized one after another and fed to the second-dimension capillary for further separation in polyacrylamide gel. During this procedure, a single CIEF band was separated into several peaks due to different molecular weights. The resulting electrophoregram is quite different from that of either CIEF or CGE; therefore, more information about the studied Hb sample can be obtained.     

Backscattering of Scholte waves and near-grazing underwater acoustic waves by a trench at a liquid/solid interface

Ultrasonic modeling results are presented on backscattering of broadband pulsed Scholte waves and grazing underwater acoustic waves from a trench at a liquid/solid interface. The backscattered waves are characterized by interference of diffracted waves reflected from the trench bottom and the trailing steep side. The effects of trench width and depth are demonstrated.     

Field amplified separation in capillary electrophoresis: a capillary electrophoresis mode

In field-amplified injection in capillary electrophoresis (CE), the capillary is filled with two buffering zones of different ionic strength; this induces an amplified electrical field in the low ionic strength zone and a lower field in the high ionic strength zone, making sample stacking feasible. The electroosmotic flow (eof) usually observed in CE, however, displaces the low field zone and induces an extra band broadening preventing any CE separation in the field-amplified zone. These limitations have originated the restricted use of field amplification in CE only for stacking purposes. For the first time, in this work it is theoretically shown and experimentally corroborated that CE separation speed and efficiency can simultaneously be increased if the whole separation is performed in the field-amplified zone, using what we have called field amplified separation in capillary electrophoresis (FAsCE). The possibilities of this new CE mode are investigated using a new and simple coating able to provide near-zero eof at the selected separation pH. Using FAsCE, improvements of 20% for separation speed and 40% for efficiency are achieved. Moreover, a modified FAsCE approach is investigated filling the capillary with the high ionic strength buffer up to the interior of the detection window. Under these conditions, an additional 3-fold increase in sensitivity is also observed. The most interesting results were obtained combining the short-end injection mode and this modified FAsCE approach. Under these conditions, a part of a 3-fold improvement in efficiency and sensitivity, the total analysis time was drastically reduced to 40 s, giving rise to a time reduction of more than 7-fold compared to normal CE. This speed enhancement brings about one of the fastest CE separations achieved using capillaries, demonstrating the great possibilities of FAsCE as a new, sensitive, efficient, and fast CE separation mode.     

Mechanism of arsenate coprecipitation at the solid/liquid interface of ferrihydrite: A perspective review

Arsenate (As(V)) is a toxic element in acid mine drainage and has to be removed during the neutralization process. Coprecipitation with ferrihydrite is the main mechanism for As(V) removal from acid mine drainage. To improve treatment efficiency, a quantitative understanding of the coprecipitation mechanism is required. Coprecipitation can incorporate more As(V) into ferrihydrite than adsorption. The results of XRD (X-ray Diffraction) and XANES (X-ray Adsorption Near Edge Structure) analysis confirmed that the formation of poorly crystalline ferric arsenate increased when the initial As/Fe molar ratio increased in the coprecipitation with ferrihydrite. EXAFS (Extended X-ray Adsorption Fine Structure) analysis at the iron K-edge showed that the proportion of octahedral structures in ferrihydrite increased when the initial As/Fe molar ratio increased. Moreover, EXAFS analysis at the arsenic K-edge, assuming three kinds of surface complexes for the AsFe bond, revealed that the coordination number for AsFe with an atomic distance of 2.85 × 10⁻¹⁰ m increased and that for As-Fe with an atomic distance of 3.24 × 10⁻¹⁰ m decreased as the initial As/Fe molar ratio increased. Thus, for more efficient wastewater treatment, active control of coprecipitation phenomena according to mechanistic details is essential.     

Total internal reflection fluorescence correlation spectroscopy for counting molecules at solid/liquid interfaces

Fluorescence correlation spectroscopy, using tota internal reflection excitation (TIRFCS), is developed as a method to allow quantitative determination of molecular populations at solid/liquid interfaces. Population fluctuations of fluorescent molecules at the interface are observed as excess low-frequency noise on a fluorescence signal. Since the noise arises from molecular origins, its magnitude can be evaluated by Poisson statistics to determine the number of molecules in the interface volume. This quantitative information is available without sensitivity calibration or the preparation of standards and without fitting the transients to a kinetic model. Unlike single-molecule counting measurements, TIRFCS can produce these quantitative results even when the number of photoelectrons detected per molecule is small. Surface populations of rhodamine 6G dye molecules were measured at C-18-derivatized, flat silica surfaces in contact with aqueous solutions and compared with predicted values derived from chromatographic retention data. In addition, electrostatic and nonpolar contributions to the free energy of adsorption of the dye to C-18-modified silica surfaces were examined.     

A low-flow ce/electrospray ionization MS interface for capillary zone electrophoresis,large-volume sample stacking,and micellar electrokinetic chromatography

A simple and versatile low-flow interface has been developed for interfacing capillary electrophoresis (CE) with electrospray ionization (ESI) mass spectrometry. This low-flow interface showed better sensitivity than a conventional sheath liquid interface, primarily attributed to a low dilution factor and a reduction in the sprayer orifice size. The interface was also found to be more tolerant to the presence of nonvolatile salts. Because of tolerance to the surfactant SDS, this interface can be used to couple micellar electrokinetic chromatography (MEKC) with ESI-MS. The performance of the interface in an MEKC-MS application, as demonstrated in the analysis of triazines, was significantly better than that obtained with a conventional sheath liquid interface. Moreover, this interface can be easily used for large-volume sample-stacking (LVSS) applications. Using a series of phenols as a test case, an approximate 500-fold enrichment was achieved by LVSS in conjunction with the low-flow CE/MS interface described.     

DNA capillary electrophoresis in entangled dynamic polymers of surfactant molecules

Aqueous solutions of monomeric nonionic surfactants, n-alkyl polyoxyethylene ethers (C16E6, C16E8, C14E6), can be used as sieving matrixes for the separation of DNA fragments by capillary electrophoresis. Unlike ordinary polymer solutions, these surfactant solutions behave as dynamic polymers. By combining the "reversible gel" theory of DNA electrophoresis and the static and dynamic properties of wormlike surfactant micelles, a model is developed for describing the migration behavior of DNA molecules in these solutions. According to the model, the separation limit can be extended at low surfactant concentrations. Surfactant solutions as a separation medium provide many advantages over ordinary polymers, such as ease of preparation, solution homogeneity, stable structure, low viscosity, and self-coating property for reducing electroosmotic flow. More importantly, the properties of wormlike micelles (micelle size, entanglement concentration) can be adjusted by simply changing the monomer concentration, denaturant, and temperature to allow the separation of different size ranges of DNA fragments. Fast separation is achieved for DNA fragments ranging from 10 bp to 5 kb by using bare fused-silica columns. DNA sequencing fragments of BigDye G-labeled M13 up to 600 bases were separated within 60 min.     

Models describing the interaction of particles with a plane solid/liquid interface

Various models depicting particle engulfment or rejection in contact with a plane organic solidification front have been examined and their predictions compared with the experimental results for six particle/matrix systems. The directionally solidified composites were made of different kinds of particles such as nylon, teflon or polystyrene dispersed within biphenyl or naphthalene matrices. The thermodynamic and thermal approaches achieve a good agreement with the experimental results for low solidification rate and particle volume fraction. In order to make the particle engulfment or rejection modelling more complete, a kinetic approach has been developed considering a critical interface velocity above which particles are engulfed and below which particles are pushed. Unfortunately, the related model did not allow the behaviour of particles in front of a plane solid/liquid interface to be successfully predicted.Nomenclature C _P particle specific heat - C _L liquid specific heat - a ₀ atomic spacing - V ₀ atomic volume - kT Boltzman factor - L heat of solidification - r _P particle radius - V _C critical velocity - V _y solidification rate - _L liquid thermal conductivity - _P particle thermal conductivity - _L liquid density - _P particle density - _PL particle/liquid interfacial energy - _PS particle/solid interfacial energy - G _net change in free energy for engulfment - k constant - A empirical constant - b empirical constant - D diffusion coefficient of the liquid - n constant depending on the particle/matrix system     

Anomalous radial migration of single DNA molecules in capillary electrophoresis

We report the unexpected radial migration of DNA molecules in capillary electrophoresis (CE) with applied Poiseuille flow. Such movement can contribute to anomalous migration times, peak dispersion, and size and shape selectivity in CE. When Poiseuille flow is applied from the cathode to the anode, DNA molecules move toward the center of the capillary, forming a narrow, highly concentrated zone. Conversely, when the flow is applied from the anode to the cathode, DNA molecules move toward the walls, leaving a DNA-depleted zone around the axis. We showed that the deformation and orientation of DNA molecules under Poiseuille flow was responsible for the radial migration. By analyzing the forces acting on the deformed and oriented DNA molecules, we derived an expression for the radial lift force, which explained our results very well under different conditions with Poiseuille flow only, electrophoresis only, and the combination of Poiseuille flow and electrophoresis. Factors governing the direction and velocity of radial migration were elucidated. Potential applications of this phenomenon include an alternative to sheath flow in flow cytometry, improving precision and reliability of single-molecule detection, reduction of wall adsorption, and size separation with a mechanism akin to field-flow fractionation. On the negative side, nonuniform electroosmotic flow along the capillary or microfluidic channel is common in CE, and radial migration of certain analytes cannot be neglected.     

Adaptation of a thermospray liquid chromatography/mass spectrometry interface for use with alkaline anion exchange liquid chromatography of carbohydrates

An interface is described that allows the direct coupling of high-performance alkaline anion exchange liquid chromatography with thermospray mass spectrometry. A membrane suppressor is used to remove nonvolatile alkaline salts from the mobile phase after the chromatographic process is completed and prior to introduction into the mass spectrometer. Examples are given of both isocratic and gradient separations of a three-component test mixture of N-acetylated mono- and disaccharides, followed by on-line mass spectral data acquisition. Sensitivity studies show minimum detection limits for the test compounds to be in the microgram range.     

Characterization of the microdialysis junction interface for capillary electrophoresis/microelectrospray ionization mass spectrometry

A capillary electrophoresis/electrospray ionization mass spectrometry (CE/ESI-MS) interface, based on an electric circuit across a microdialysis membrane surrounding a short capillary segment closely connected to the separation capillary terminus, is demonstrated to be sensitive, efficient, and rugged. A microspray type ionization emitter produces a stable electrospray at the low flow rates provided by CE and thus avoids both the need for a makeup liquid flow provided by liquid junction or sheath flow interfaces and the subsequent dilution and reduction in sensitivity. Reproducibility studies and comparisons with CE/UV and the CE/sheath flow interface with ESI-MS are presented. Additionally, postrun acidification via the microdialysis junction interface is demonstrated and shown to be capable of denaturing the holomyoglobin protein noncovalent complex while maintaining separation efficiency.     

Self-assembly of modified silica nanospheres at the liquid/liquid interface

A stabilized 2 or 3D silica sphere structure was successfully prepared by a 3-step method. First, the surfaces of silica spheres were modified with a functional silane coupling agent 3-methacryloxypropyltrimethoxysilane (γ-MPS); then, the surface-modified silica spheres were self-assembled at the liquid/liquid interface to fabricate a two- or three-dimensional ordered structure; and finally, the formed ordered structure was stabilized by a stable polymerization reaction among the modified silica spheres. The polymerized silica sphere film can be transferred from solution to quartz substrates without destroying its ordered structure. This ordered structure could be potentially used as a photonic band gap material or the template for fabrication of other highly ordered structures.     

Controlled synthesis of Au nanoplates at the liquid/liquid interface

Large-size single-crystal Au nanoplates have been successfully prepared by fluorescent light irradiation into the diethyl ether/aqueous solution of HAuCl₄ biphasic mixture in the presence of 1,3-diaminopropane (DAP). The products morphology depends on the pH of reaction solution. Au nanoplates were formed at pH below the pKa value of DAP. However, spherical particles were produced under alkaline conditions. These results show that DAP plays a key role in the determination of particle morphology. Properties of the nanoplates were studied by scanning electron microscopy, transmission electron microscopy, and X-ray diffraction.     

Time-resolved total internal reflection fluorometry study on polarity at a liquid/liquid interface

The polarity of a water/oil (oil: cyclohexane, carbon tetrachloride, toluene, chlorobenzene, o-dichlorobenzene, or 1,2-dichloroethane) interface was investigated by means of time-resolved total-internal-reflection (TIR) fluorescence spectroscopy of a polarity-sensitive probe: sulforhodamine B (SRB). In bulk solutions, the nonradiative decay rate constant of SRB increased with an increase in a solvent polarity parameter [ET(30)], and this relationship was used to estimate the polarities of water/oil interfaces. For the oil having a relatively low solvent polarity [ET(30) < 35 kcal/mol], the polarity of the water/ oil interface agreed with that of the arithmetic average of the polarities of the two phases [ET(30)calc]. For water/odichlorobenzene and water/1,2-dichloroethane interfaces [ET(30) of the oil > 35 kcal/mol], on the other hand, the interfacial polarity determined by TIR spectroscopy was lower than the ET(30)calc. The results are discussed in terms of thickness/roughness of the water/oil interface.