Electric Field Enhanced Plasmid Delivery to Liver Hepatocellular Carcinomas

Abstract

Electric field enhanced molecular delivery for cancer research and treatment is a new technology that has demonstrated its effectiveness in clinical trials using bleomycin or cisplatin (Heller, R., Gilbert, R., Jaroszeski, M. J. Clinical applications of electrocemotherapy. Advanced Drug Delivery Reviews 35, 119–129 (1999)), as chemotherapeutic agents. The technology is being investigated in research applications for applicability as a method to enhance gene expression in a target tumor. Success is predicated on an appropriate effective electric field mediated delivery protocol that triggers significant appropriate gene expression duration and levels.

An electric field mediated delivery protocol includes a set of conditions associated with the electric field, the electroporation signature, as well as parameters associated with the plasmid and the electric field applicator. Manipulation of the electrical parameters within the electroporation signature generates different gene expression levels in liver hepatocellular carcinomas. Statistically significant gene expression levels were obtained that differed by an order of magnitude when two different electric field strength and duration conditions were employed.

Keywords

electroporation hepatocellular liver carcinomas

References

Yamashita

, Shimada

, Hasegawa

, Minagawa

, Rikimaru

, Hamatsu

, Tanaka

, Shirabe

, Miyazaki

, Sugimachi

Electroporation-mediated interkeukin-12 gene therapy for hepatocellular carcinoma in the mice model. Cancer Res. 61, 1005 (2001).

Rols

, Delteil

, Golzio

, Dumond

, Cros

, Teissie

In vivo electrically mediated protein and gene transfer in murine melanoma. Nature Biotech. 16, 168–171 (1998).

Heller

L. C.

, Pottinger

, Jaroszeski

M. J.

, Gilbert

, Heller

In vivo electroporation of plasmids encoding GMCSF and interleukin-2 into existing B16 melanomas combined with electrochemotherapy induces long term antitumor immunity. Melanoma Research, 10, 577–583 (2000).

Vicat

J. M.

, Boisseau

, Jourdes

, Laine

, Wion

, Bouali-Benazzouz

, Benabid

, Berger

Muscle transfection by electroporation with high voltage and short pulse currents provides high-level and long lasting gene expression. Human Gene Ther. 11, 909–916 (2000).

Nishi

, Yoshizato

, Yamashiro

, Takeshima

, Sato

, Hamada

, Kitamura

, Yoshimura

, Saya

, Kuratsu

, Ushio

High-efficiency in vivo gene transfer using intraarterial plasmid DNA injection following in vivo electroporation. Cancer Res. 56, 1050–1055 (1996).

Electrically Mediated Delivery of Molecules to Cells-Electrochemotherapy, Electrogenetherapy, and Transdermal Delivery by Electroporation. Eds. Jaroszeski

M. J.

, Gilbert

, and Heller

Humana Press, Totowa, NJ (2000).

Lucas

M. L.

, Jaroseski

M. J.

, Gilbert

, Heller

In Vivo electroporation using an expoentially enhanced pulse: a new waveform. DNA and Cell Biology 20, 183–188 (2001).

Bureau

M. F.

, Gehl

, Deleuze

, Mir

L. M.

, Scherman

Importance of association between permeabilization and electrophoretic forces for intramuscular DNA electrotransfer. Biochimica et Biophysica Acta 1474, 353–9 (2000).

Satkauskas

, Bureau

M. F.

, Puc

, Mahfoudi

, Scherman

, Miklavcic

, Mir

L. M.

Mechanisms of in vivo DNA electrotransfer: respective contributions of cell electropermeabilization and DNA electrophoresis. Mol. Therapy 5, 133–140 (2002).

10.

Aihara

, Miyazaki

Gene transfer into muscle by electroporation in vivo. Nature Bioechnol. 16, 867–870 (1998).

11.

Mir

, Bureau

, Gehl

, Rangara

, Rouy

, Cailaud

, Delaere

, Branellec

, Schwartz

, Scherman

High-efficiency gene transfer into skeletal muscle mediated by electric pulse. Proc. Natl. Acad. Sci. USA 96, 4262–4267 (1999).

12.

Lucas

M. L.

, Heller

, Coppola

, Heller

IL-12 Plasmid Delivery by In Vivo Electroporation for the sucessful teatment of established subcuntaneous B16.F10 melanoma. Molecular Therapy 5, 668–675 (2002).

13.

Lucas

M. L.

, Heller

Imunomodulation by electrically enhanced delivery of plasmid DNA encoding IL 12 to murine skeletal muscle. Molecular Therapy 3, 47–53 (2001).

14.

Heller

, Jaroszeski

, Atkin

, Moradpour

, Gilbert

, Wands

, Nicolau

In vivo gene electroinjection and expression in rat liver. Fed. Europ. Biochem. Soc. (FEBS) Letters 389, 225–228 (1996).

15.

Heller

, Jaroszeski

M. J.

, Coppola

, Pottinger

, Gilbert

and Heller

Electrically mediated plasmid DNA delivery to hepatocellular carcinomas in vivo. Gene Therapy 7, 826–829 (2000).