print small

Participating Countries:

Algeria

Argentina

Australia

Austria

Belgium

Bosnia and Herzegovina

Bulgaria

Croatia

Czech Republic

Denmark

Finland

France

FYR of Macedonia

Germany

Greece

Iceland

Ireland

Israel

Italy

Lithuania

Morocco

Netherlands

New Zealand

Poland

Portugal

Romania

Russian Federation

Serbia

Slovenia

Spain

Sweden

Switzerland

Turkey

Ukraine

United Kingdom

United States

Member area provided by LTFE
COST is supported by the EU Framework Programme Horizon 2020
This website is supported by COST
02/04/2015 (Added to site)
Author(s): Xu, Y.; Su, S.; Zhou, C.; Lu, Y.; Xing, W.

Cell electroporation with a three-dimensional microelectrode array on a printed circuit board

Journal: Bioelectrochemistry, 102/1 (2015), pp. 35-41
DOI: 10.1016/j.bioelechem.2014.10.002
Request reprint  |  Tell your friend  | 

Abstract: Electroporation is a commonly used approach to rapidly introduce exogenous molecules into cells without permanent damage. Compared to classical electroporation protocols, microchip-based electroporation approaches have the advantages of high transfection efficiency and low consumption, but they also commonly rely on costly and tedious microfabrication technology. Hence, it is desirable to develop a novel, more affordable, and effective approach to facilitate cell electroporation. In this study, we utilized a standard printed circuit board (PCB) technology to fabricate a chip with an interdigitated array of electrodes for electroporation of suspended cells. The electrodes (thickness ~35 μm) fabricated by PCB technology are much thicker than the two-dimensional (2D) planar electrodes (thickness < 1 μm) fabricated by conventional microfabrication techniques and possess a smooth corner edge. Numerical simulations showed that the three-dimensional (3D) electrodes fabricated by PCB technology can provide a more uniformly distributed electric field compared to 2D planar electrodes, which is beneficial for reducing the electrolysis of water and improving cell transfection efficiency. The chip constructed here is composed of 18 individually addressable wells for high throughput cell electroporation. HeLa, MCF7, COS7, Jurkat, and 3T3-L1 cells were efficiently transfected with the pEGFP-N1 plasmid using individually optimal electroporation parameters. This work provides a novel method for convenient and rapid cell transfection and thus holds promise for use as a low-cost disposable device in biomedical research.


Keywords: 3D    electroporation    printed circuit board    transfection   

Project Office

Working groups

Steering Committee

Founding members

DC Rapporteurs

Related sites: