Chip electrochromatography of polycyclic aromatic hydrocarbons on an acrylate-based UV-initiated porous polymer monolith

The first rigorous evaluation of a UV-initiated porous polymer monolith (PPM) as a stationary phase for chip electrochromatography (ChEC) is described. All channels in an offset T-injector-design-chip (25-mum deep by 50-mum wide channels) were filled by capillary action with an acrylate-based PPM precursor solution and polymerized in situ using 365 nm light for several minutes. Photodefinability of the monolith cast in the channels during the polymerization process was also demonstrated by masking off the injection arms during photoinitiation. The chromatographic performance of this chip was compared with that of chips completely filled with monolith. The detection window was photodefined after polymerization using the detection laser (257 nm doubled argon ion laser) to depolymerize the detection window. A successful ChEC separation of 10 out of 13 polycyclic aromatic hydrocarbons (PAH) was performed with on-column, off-packing laser-induced fluorescence detection at 257 nm. Van Deemter plots for early-, middle-, and late-eluting compounds showed the minimum plate height to be 5 mum. The average number of theoretical plates per meter for the PAH was 200,000. Several factors contributed to irreproducible results. Oxygen was observed to dynamically quench the fluorescence of the sample over time. Improved sealing of the reservoirs solved this problem. A within-chip variability in the retention time of 2-10% RSD was observed. These results demonstrate the feasibility and reliability of the PPM as a solid reversed-phase for electroosmotic flow-driven chip-based chromatography in microscale total analysis systems.