A microflow cytometer with simultaneous dielectrophoretic actuation for the optical assay and capacitive cytometry of individual fluid suspended bioparticles

• Main Author: Romanuik, Sean
• Other Authors: Thomson, Douglas (Electrical and Computer Engineering)
• Language: en_US
• Published: 2009
• Subjects: Microflow; Microfluidic; Cytometer; Cytometry; Dielectrophoretic; Dielectrophoresis; Interferometer; Interferometric; Capacitive Sensor; Capacitance Sensing; Capacitive Detector; Capacitance Detection; Polystyrene; Optical Assay; Electrokinetic; Actuation; Yeast; Saccharomyces cerevisiae; Single-cell Diagnostic; Single-cell Diagnosis; Dielectric Modeling; COMSOL; Tracker; Trajectory; Velocity Profile; Capacitive Signature; Capacitance Signature; Microelectrode
• Online Access: http://hdl.handle.net/1993/3205

Fluid suspended biological particles (bioparticles) flowing through a non-uniform electric field are actuated by the induced dielectrophoretic (DEP) force, known to be dependent upon the bioparticles’ dielectric phenotypes. In this work: a 10-1000 kHz DEP actuation potential applied to a co-planar microelectrode array (MEA) induces a DEP force, altering passing bioparticle trajectories as monitored using: (1) an optical assay, in which the lateral bioparticle velocities are estimated from digital video; and (2) a capacitive cytometer, in which a 1.478 GHz capacitance sensor measures the MEA capacitance perturbations induced by passing bioparticles, which is sensitive to the bioparticles’ elevations. The experimentally observed and simulated lateral velocity profiles of actuated polystyrene microspheres (PSS) and viable and heat shocked Saccharomyces cerevisiae cells verify that the bioparticles’ dielectric phenotypes can be inferred from the resultant trajectories due to the balance between the DEP force and the viscous fluid drag force.