Monolithic microextraction tips by emulsion photopolymerization

Monoliths formed by photopolymerization are excellent means for fabricating functional elements in miniaturized microdevices such as microextraction tips which are becoming important for sample preparation. Various silica-based and polymer-based materials have been used to fabricate monoliths with through pores of several nm to 4 μm. However, the back pressure created by such methods is still considered to be high for microtips that use suction forces to deliver the liquid. In this study, we demonstrated that emulsion techniques such as oil-in-water can be used to form monoliths with large through pores (>20 μm), and with rigid structures on small (10 μL) and large (200 μL) pipette tips by photopolymerization. We further showed that, with minor modifications, various functionalized particles (5–20 μm) can be added to form stable emulsions and successfully encapsulated into the monoliths for qualitative and quantitative solid-phase microextractions for a diverse application. Due to high permeability and large surface area, quick equilibration can be achieved by pipetting to yield high recovery rates. Using tryptic digests of ovalbumin as the standard, we obtained a recovery yield of 90–109% (RSD: 10–16%) with a loading capacity of 3 μg for desalting tips immobilized with C18 beads. Using tryptic digests of β-casein and α-casein as standards, we showed that phosphopeptides were substantially enriched by tips immobilized with immobilized metal affinity chromatography or TiO2 materials. Using estrogenic compounds as standards, we obtained a recovery yield of 95–108% (RSD: 10–12%) and linear calibration curves ranging from 5 to 100 ng (R2 > 0.99) for Waters Oasis HLB tips immobilized with hydrophilic beads.