@article{38208b6a749c40eba9d277c1b635f4a3,
title = "Real time electroporation control for accurate and safe in vivo non-viral gene therapy",
abstract = "In vivo cell electroporation is the basis of DNA electrotransfer, an efficient method for non-viral gene therapy using naked DNA. The electric pulses have two roles, to permeabilize the target cell plasma membrane and to transport the DNA towards or across the permeabilized membrane by electrophoresis. For efficient electrotransfer, reversible undamaging target cell permeabilization is mandatory. We report the possibility to monitor in vivo cell electroporation during pulse delivery, and to adjust the electric field strength on real time, within a few microseconds after the beginning of the pulse, to ensure efficacy and safety of the procedure. A control algorithm was elaborated, implemented in a prototype device and tested in luciferase gene electrotransfer to mice muscles. Controlled pulses resulted in protection of the tissue and high levels of luciferase in gene transfer experiments where uncorrected excessive applied voltages lead to intense muscle damage and consecutive loss of luciferase gene expression.",
keywords = "DNA electrotransfer, Electrochemotherapy, Electropermeabilization, Electroporation, Finite element modeling, Gene therapy",
author = "David Cukjati and Danute Batiuskaite and Franck Andr{\'e} and Damijan Miklav{\v c}i{\v c} and Mir, {Lluis M.}",
note = "Funding Information: This research was supported by the CNRS, the Institut Gustave–Roussy and the Cliniporator project (FP5, Contract No. QLK3–1999–00484) of the European Community. We also acknowledge the staff of the Service Commun d'Exp{\'e}rimentation Animale (M. P. Ardouin) of the Institut Gustave–Roussy for animal maintenance, and France T{\'e}l{\'e}com (Dr. J. Wiart) for the generous loan of the oscilloscope and the recording material (probes, portable computer and software). The authors are in debt to Selma {\v C}orovi{\'c} (Faculty of Electrical Engineering, University of Ljubljana, Slovenia) for her finite element modeling of electric field strength distribution in tissues and to Claudio Bertacchini (IGEA s.r.l., Carpi, Italy) for testing the algorithm ex-vivo on tissue.",
year = "2007",
month = may,
day = "1",
doi = "10.1016/j.bioelechem.2006.11.001",
language = "English",
volume = "70",
pages = "501--507",
journal = "Bioelectrochemistry",
issn = "1567-5394",
number = "2",
}