Title :
EIT-Inspired Microfluidic Cytometer for Single-Cell Dielectric Spectroscopy
Author :
Caselli, Federica ; Bisegna, Paolo ; Maceri, Franco
Author_Institution :
Dept. of Civil Eng., Univ. of Rome Tor Vergata, Rome, Italy
Abstract :
A new microfluidic cytometer for single-cell dielectric spectroscopy is proposed in this paper and analyzed in silico by means of a finite-element model. The device, inspired by electrical impedance tomography, includes two circumferential arrays of electrodes instead of just two pairs of coplanar or parallel-facing electrodes, thus allowing a great versatility in stimulation and measurement patterns. In particular, using stimulation patterns with different spatial orientation provides information on cell morphology, besides quantitative cell-volume estimation. Moreover, the performance limitation at low frequency due to electrode polarization is overcome, owing to a peculiar recording scheme: Current is injected between an electrode pair, and the resulting voltages are measured at remaining electrodes using high-input impedance differential amplifiers. These features significantly enhance the cytometer discrimination capabilities.
Keywords :
bioMEMS; bioelectric phenomena; biomedical electrodes; cellular biophysics; dielectric polarisation; differential amplifiers; electric impedance imaging; finite element analysis; microfluidics; EIT-inspired microfluidic cytometer; cell morphology; circumferential arrays; coplanar electrode pairs; cytometer discrimination capabilities; electrical impedance tomography; electrode polarization; electrodes; finite-element model; high-input impedance differential amplifiers; parallel-facing electrodes; quantitative cell-volume estimation; single-cell dielectric spectroscopy; spatial orientation; stimulation patterns; Atmospheric measurements; Biomembranes; Current measurement; Dielectrics; Electrodes; Impedance; Voltage measurement; Biological cells; biomedical equipment; biomedical impedance imaging; distributed parameter circuits; finite-element methods; microelectrodes; microfluidics; modeling; shape measurement; volume measurement;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2010.2067204
