Hamed Eghbali

Performance evaluation of long monolithic silica capillary columns in gradient liquid chromatography using peptide mixtures

A systematic study is reported on the performance of long monolithic capillary columns in gradient mode. Using a commercial nano-LC system, reversed-phase peptide separations obtained through UV-detection were conducted. The chromatographic performance, in terms of conditional peak capacity and peak productivity, was investigated for different gradient times (varying between 90 and 1320min) and different column lengths (0.25, 1, 2 and 4m) all originating from a single 4m long column. Peak capacities reaching values up to n=10(3) were measured in case of the 4m long column demonstrating the high potential of these long monoliths for the analysis of complex biological mixtures, amongst others. In addition, it was found that the different column fragments displayed similar flow resistance as well as consistent chromatographic performance in accordance with chromatographic theory indicating that the chromatographic bed of the original 4m long column possessed a structural homogeneity over its entire length.

Effect of the presence of an ordered micro-pillar array on the formation of silica monoliths

We report on the synthesis of siloxane-based monoliths in the presence of a two-dimensional, perfectly ordered array of micro-pillars. Both methyltrimethoxysilane- and tetramethoxysilane-based monoliths were considered. The obtained structures were analyzed using scanning-electron microscopy and can be explained from the general theory of surface-directed phase separation in confined spaces. The formed structures are to a large extent nearly exclusively determined by the ratio between the bulk domain size of the monolith on the one hand and the distance between the micro-pillars on the other hand. When this ratio is small, the presence of the pillars has nearly no effect on the morphology of the produced monoliths. However, when the ratio approaches unity and ascends above it, some new types of monolith morphologies are induced, two of which appear to have interesting properties for use as novel chromatographic supports. One of these structures (obtained when the domain size/inter-pillar distance ratio is around unity) is a 3D network of linear interconnections between the pillars, organized such that all skeleton branches are oriented perpendicular to the micro-pillar surface. A second interesting structure is obtained at even higher values of the domain size/inter-pillar distance ratio. In this case, each individual micro-pillar is uniformly coated with a mesoporous shell.

Experimental Investigation of the Band Broadening Arising from Short-Range Interchannel Heterogeneities in Chromatographic Beds under the Condition of Identical External Porosity

The interesting possibilities offered by micropillar array columns to investigate the relation between bed heterogeneity and band broadening in chromatographic columns are illustrated and investigated. The perfect control over the microscopic bed structure offered by the photolithographic fabrication technique could be used to produce a heterogeneous bed displaying a short-range interchannel heterogeneity and having exactly the same particle size and external porosity as the perfectly ordered bed that was used as the reference system. According to this approach, any observed difference in band broadening could be directly owed to the effect of the bed heterogeneity. Knowing that the only difference between the investigated beds was their degree of heterogeneity, the obtained plate height measurements provided a unique test to distinguish among the abilities to recognize short-range interchannel heterogeneity of the different existing plate height models. Interpreting the data with the classical van Deemter and Knox models, it was found that the increased bed heterogeneity leads not only to an increase in the A-term constant but also to a clear increase in the C-term constant.

Design and performance evaluation of a microfluidic ion-suppression module for anion-exchange chromatography

A microfluidic membrane suppressor has been constructed to suppress ions of alkaline mobile-phases via an acid-base reaction across a sulfonated poly(tetrafluoroethylene)-based membrane and was evaluated for anion-exchange separations using conductivity detection. The membrane was clamped between two chip substrates, accommodating rectangular microchannels for the eluent and regenerant flow, respectively. Additionally, a clamp-on chip holder has been constructed which allows the alignment and stacking of different chip modules. The response and efficacy of the microfluidic chip suppressor was assessed for a wide range of eluent (KOH) concentrations, using 127 and 183μm thick membranes, while optimizing the flow rate and concentration of the regenerant solution (H2SO4). The optimal operating eluent flow rate was determined at 5μL/min, corresponding to the optimal van-Deemter flow velocity of commercially-available column technology, i.e. a 0.4mm i.d.×250mm long column packed with 7.5μm anion-exchange particles. When equilibrated at 10mM KOH, a 99% decrease in conductivity signal could be obtained within 5min when applying 10mM H2SO4 regenerant at 75μL/min. A background signal as low as 1.2μS/cm was obtained, which equals the performance of a commercially-available electrolytic hollow-fiber suppressor. When increasing the temperature of the membrane suppressor from 15 to 20°C, ion suppression was significantly improved allowing the application of 75mM KOH. The applicability of the chip suppressor has been demonstrated with an isocratic baseline separation of a mixture of seven inorganic ions, yielding plate numbers between 5300 and 10,600 and with a gradient separation of a complex ion mixture.

Use of non-porous pillar array columns for the separation of Pseudomonas pyoverdine siderophores as an example of a real-world biological sample.

We report on the first separation of a complex biomixture in pressure-driven mode using perfectly ordered pillar array columns. The separations were conducted in the reversed-phase mode using a highly aqueous mobile phase, while the outer surface of the non-porous pillars was chemically functionalized with a hydrophobic C8-layer. The samples originated from two different bacterial strains (Pseudomonas aeruginosa PAO1 and Pseudomonas sp. W15Feb38) of fluorescent pseudomonads. These produce fluorescent yellow-green pyoverdines that serve as siderophores to shuttle iron inside the cell. The pyoverdines of both strains were prepared from the supernatant through a crude solid phase extraction without any further purification step. In case of the PAO1 mixture, a separation of 15 components within a column length of 2.5 cm could be observed through the transparent cover glass of the chip. For the W15Feb38 mixture, a separation of eight components could be observed within the same distance. These fast chromatographic separations were compared with those obtained via iso-electrofocusing (IEF), which is the traditionally employed fingerprinting method to characterize pseudomonad strains based on their pyoverdine profiles (siderotyping). With this technique, and despite the injection of a 10,000 times larger sample mass, only nine bands were maximally observed for the PAO1 mixture, whereas maximally six bands were observed in case of the W15Feb38 mixture. The chromatographic pillar array method, yielding a separation in less than 1 min, was also significantly faster than the IEF method, which typically needs 1.5h. The present system can therefore be considered as a potential alternative fingerprinting tool for the fast identification of different strains of fluorescent pseudomonads, including as diagnostic tool for typing strains of the important opportunistic pathogen P. aeruginosa.

Performance evaluation of ion‐exchange chromatography in capillary format

The performance of a recently introduced capillary ion-exchange chromatography system was explored. Experiments were conducted in isocratic mode with a commercial capillary anion-exchange column (id = 0.4 mm, L = 15 cm) using a five-anion standard mixture. The achieved results were compared to the performance of a standard bore ion-exchange system (id = 4 mm, L = 15 cm), which was considered as a reference. The first-generation capillary columns exhibited a minimal reduced plate-height value below two witnessing a good packing quality and system performance. However, compared to the standard bore system the capillary system displayed an increased apparent C-term which could be due to a difference in packing morphology and/or possible external band-broadening contributions. For fast separations, the standard bore system outperformed the capillary system, while for complex separations both systems performed nearly equally well. In addition, the retention characteristics of the capillary system were investigated. To illustrate the suitability of the capillary system, the analysis of real-world water samples originating from two local Belgian rivers was demonstrated.

Improved Liquid Phase Chromatography Separation using Sub-micron Micromachining Technology

While liquid phase chromatography is using macroscopic columns filled with micron scale particles, a major separation enhancement is expected when using perfectly ordered (sub-) micron structures. Therefore an on-wafer chromatograph was fabricated using advanced micromachining technology. The first characterization results are presented and compared to the performance of state-of-the-art macroscopic devices.

The axial rearrangement mixer: working principles and in-depth investigation.

In the current paper, an axial rearrangement mixer is studied. The mixer aims to flatten out occasional composition fluctuations originating from the pump. In a first phase, dispersion in a single mixer channel is investigated using pulses introduced by a dedicated injection pulse generator. The mixing in the single channel is studied for different flow rates and a model is presented based on the experimental data. Next, the resulting signal for the whole mixer is studied.