All-electronic detection and actuation of single biological cells for lab-on-a-chip applications

Author

Romanuik, S.F. ; Ferrier, G.A. ; Thomson, D.J. ; Bridges, G.E. ; Olson, S. ; Freeman, M.R.

Author_Institution

Electr. & Comput. Eng., Univ. of Manitoba, Winnipeg, MB

fYear

2008

fDate

26-29 Oct. 2008

Firstpage

634

Lastpage

637

Abstract

A device sensing the change in capacitance as single cells flow through a microfluidic channel past interdigitated electrodes is described. A 0.45 aF resolution within a 3 ms time constant has been achieved. A cellpsilas electrical properties can vary greatly due to ionic currents, double layer effects, and membrane potential gradients (particularly when operating below 200 MHz). Sensing at microwave frequencies (1.6 GHz) greatly reduces these effects. Cells are simultaneously actuated by superimposing a low frequency (LF) signal, producing a dielectrophoretic (DEP) force. As the signal varies with the cellpsilas elevation, the relative magnitude and sign of the DEP force is inferred, without optical sensing.

Keywords

bioMEMS; bioelectric potentials; biomembrane transport; capacitive sensors; cellular biophysics; electrophoresis; lab-on-a-chip; microchannel flow; microwave measurement; all-electronic detection; cell electrical properties; cell elevation; dielectrophoretic force; double layer effects; frequency 1.6 GHz; interdigitated electrodes; ionic currents; lab-on-a-chip application; low-frequency signal; membrane potential gradients; microfluidic channel; microwave interferometer; single biological cell actuation; time constant; Biological cells; Biomembranes; Couplings; Dielectrophoresis; Electrodes; Impedance; Lab-on-a-chip; Microfluidics; Microwave frequencies; Optical sensors;

fLanguage

English

Publisher

ieee

Conference_Titel

Sensors, 2008 IEEE

Conference_Location

Lecce

ISSN

1930-0395

Print_ISBN

978-1-4244-2580-8

Electronic_ISBN

1930-0395

Type

conf

DOI

10.1109/ICSENS.2008.4716521

Filename

4716521