Feasibility Study for Cell Electroporation Detection and Separation by Means of Dielectrophoresis

Overview

Journal Bioelectrochemistry

Publisher Elsevier

Specialty Biochemistry

Date 2007 May 19

PMID 17509948

Citations 10

Authors

Jakob Oblak

Dejan Krizaj

Slavko Amon

Alenka Macek-Lebar

Damijan Miklavcic

Affiliations

Soon will be listed here.

Abstract

Electroporation is a phenomenon during which exposure of a cell to high voltage electric pulses results in a significant increase in its membrane permeability. Aside from the fact that after the electroporation the cell membrane becomes more permeable, the cells' geometrical and electrical properties change considerably. These changes enable use of the force on dielectric particles exposed to non-uniform electric field (dielectrophoresis) for separation of non-electroporated and electroporated cells. This paper reports the results of an attempt to separate non-electroporated and electroporated cells by means of dielectrophoresis. In several experiments we managed to separate the non-electroporated and electroporated cells suspended in a medium with conductivity 0.174 S/m by exposing them to a non-uniform electric field at a frequency of 2 MHz. The behaviour of electroporated cells exposed to dielectrophoresis raises the presumption that in addition to conductivity, considerable changes in membrane permittivity occur after the electroporation.

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