Detailed kinetic performance analysis of micromachined radially elongated pillar array columns for liquid chromatography.

The individual factors that determine the kinetic performance (B- and C-term band broadening and bed permeability Kv) of radially elongated pillar (REP) columns are studied. To this end, columns with REPs having 4 different aspect ratios (AR=9, 12, 15, 20) were characterized experimentally and by means of numerical simulations. A tortuosity and retention based plate height equation was established, enabling a good global fit for all studied conditions.

Mass-manufacturable polymer microfluidic device for dual fiber optical trapping.

We present a microfluidic chip in Polymethyl methacrylate (PMMA) for optical trapping of particles in an 80µm wide microchannel using two counterpropagating single-mode beams. The trapping fibers are separated from the sample fluid by 70µm thick polymer walls. We calculate the optical forces that act on particles flowing in the microchannel using wave optics in combination with non-sequential ray-tracing and further mathematical processing.

Merging Open-Tubular and Packed Bed Liquid Chromatography.

Experimental and theoretical proof is provided for the fact that a microfabricated packed bed column, which is uniformly filled with radially elongated pillars (REPs), can produce the same separation performance as nonpacked, open-tubular columns. These are generally recognized as the best possible chromatographic column format, offering the highest conceivable separation speed and efficiency. It is also demonstrated both experimentally and theoretically that, as long as pressure is not a limiting factor, the REP column format can even outperform the open-tubular column format, with significant gains in either speed or efficiency proportional to the tortuosity, τ, of the bed.

Assessment and numerical search for minimal Taylor-Aris dispersion in micro-machined channels of nearly rectangular cross-section.

A mathematical procedure using the Matlab® PDE toolbox to calculate the numerical constant appearing in the general Taylor-Aris expression for the dispersion in a laminar flow through open-tubular conduits with a variety of quasi-rectangular cross-sectional shapes is described. The procedure has been applied to assess the effect of some of the most frequently occurring etching imperfections (linear or curved tapering of the inter-pillar distance along the depth coordinate, occurrence of local notches) in etched pillar array columns. In addition, covering a broad range of possible geometries, a number of new shapes and optimal geometries to minimize the dispersion in open-tubular microchannels and pillar array columns have been proposed.

Suppression of the sidewall effect in pillar array columns with radially elongated pillars.

An important bottleneck of pillar array columns designed for liquid chromatography is that small deviations of the target 'magical distance' at the sidewall region leads to detrimental sidewall effects, due to local differences of linear velocities at the sidewall region versus other locations in the pillar bed. In the present study, we demonstrate that a lateral elongation of the pillar significantly increases the tolerance for offsets of the magical distance. By shifting the sidewall distance 600 nm for 2 pillar aspect ratio (AR) designs (AR=3 and 9), only minor sidewall effects on the measured plate heights could be observed for the AR=9 columns, while the plate height was roughly doubled when using the wrong versus the correct sidewall distance for the AR=3 columns.

Integration of uniform porous shell layers in very long pillar array columns using electrochemical anodization for liquid chromatography.

Electrochemical anodization has been applied to grow porous shell layers of 300 nm (30 nm pores) in 5 μm diameter pillar array columns (PACs) with a spacing of 2.5 μm. Using turn structures preceded and followed by the flow distributor structures recently introduced by our group and filled with radially elongated pillars, columns with quasi unlimited channel lengths could be conceived.

On the advantages of radially elongated structures in microchip-based liquid chromatography.

We report on the possibility to realize submicrometer plate heights using chromatographic pillar array columns filled with radially elongated diamond-shaped pillars, even when using a relatively large interpillar distance (2.5 μm) and axial pillar width (5 μm). It is demonstrated that the use of high aspect ratio radially elongated pillars which are 15 times wider in the radial than in the axial direction can lead to a fivefold reduction of the minimal plate height compared to beds filled with pillars with a similar interpillar distance but with an aspect ratio around unity (cylinders and diamonds).

A membrane microcontactor as a tool for integrated sample preparation.

A membrane microcontactor suitable to perform liquid-liquid extraction as well as evaporation in order to conduct enrichment steps in sample preparation of organ samples has been designed, fabricated, and characterized. Spacers of 100- or 200-μm high were constructed in a metal substrate with a channel width of 13 mm and the extraction kinetics in these channels was evaluated. The spacers were designed such that at the entrance and exit region a uniform flow distribution could take place and that a uniform flow profile could be guaranteed along the channel, hence allowing a large freedom in sample volume to be processed.