Mechanistic investigation of nanoparticle motion in pulsed voltage miniaturized electrical field flow fractionation device by in situ fluorescence imaging.

In our previous study, we reported a miniaturized electrical field flow fractionation device (micro-EFFF) that used a pulsed voltage (PV) to increase the effective electric field and, hence, improved the separation performance. In this work, we developed two micro-EFFFs with planar or segmented electrode design and investigated the particle movement in the flow channels under a PV. Numerical simulation was used to understand the electric field distribution in the micro-EFFFs. When the calculations for the micro-EFFF with a segmented electrode (segmented micro-EFFF) and the micro-EFFF with planar electrodes (planar micro-EFFF) are compared, a stronger electric field at the top electrode segments is found in the segmented micro-EFFF, with the strongest field at the edges of the electrode segments. Nanoparticle motion in both devices was in situ visualized by using a fluorescence microscope equipped with a CCD-camera. Results reveal that electrophoresis governs the nanoparticle movement in the planar micro-EFFF and dielectrophoresis dominates the movement in the segmented micro-EFFF. Two models are postulated to explain the experimental observations of the nanoparticle movement. The mechanistic understanding of controlling nanoparticle motion in a miniaturized environment will help the design and application of micro-EFFF for the separation of charged biomolecules (proteins and DNAs).