Title :
Theoretical Considerations of Tissue Electroporation With High-Frequency Bipolar Pulses
Author :
Arena, Christopher B. ; Sano, Michael B. ; Rylander, Marissa Nichole ; Davalos, Rafael V.
Author_Institution :
Bioelectromechanical Syst. Lab., Virginia Polytech. Inst. & State Univ., Blacksburg, VA, USA
fDate :
5/1/2011 12:00:00 AM
Abstract :
This study introduces the use of high-frequency pulsed electric fields for tissue electroporation. Through the development of finite element models and the use of analytical techniques, electroporation with rectangular, bipolar pulses is investigated. The electric field and temperature distribution along with the associated transmembrane potential development are considered in a heterogeneous skin fold geometry. Results indicate that switching polarity on the nanosecond scale near the charging time of plasma membranes can greatly improve treatment outcomes in heterogeneous tissues. Specifically, high-frequency fields ranging from 500 kHz to 1 MHz are best suited to penetrate epithelial layers without inducing significant Joule heating, and cause electroporation in underlying cells.
Keywords :
bioelectric potentials; biological tissues; biomembranes; cellular biophysics; finite element analysis; nanobiotechnology; skin; switching; Joule heating; analytical techniques; bipolar pulse; epithelial layers; finite element model; heterogeneous skin fold geometry; heterogeneous tissues; high-frequency bipolar pulse; plasma membranes; switching polarity; tissue electroporation; transmembrane potential development; Biomembranes; Dielectrics; Electric fields; Finite element methods; Mathematical model; Plasmas; Skin; Bipolar pulses; electroporation; nanosecond pulsed electric field; oscillating electric field; transmembrane potential; Electroporation; Epidermis; Finite Element Analysis; Humans; Membrane Potentials; Models, Biological; Skin Physiological Phenomena; Temperature;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2010.2102021
