Title :
Nanosecond (Gigahertz) and Microsecond (Megahertz) pulsed electric field interactions with cell membranes
Author :
Vernier, P. Thomas
Author_Institution :
Ming Hsieh Dept. of Electr. Eng., Univ. of Southern California, Los Angeles, CA, USA
Abstract :
High-intensity nanosecond pulsed electric fields permeabilize cell membranes, restructure phospholipid bilayers, cause intracellular calcium release, depolarize mitochondrial membranes, and induce apoptosis. Molecular simulations reveal the mechanism for the electric field-driven reorganization of phospholipid head groups and water molecules that results in the formation of membrane-spanning water bridges and conductive pores. Progress has been made in taking nanosecond electric pulses to the clinic for the treatment of skin cancers and other lesions, but a deeper understanding of the underlying biophysical phenomena will facilitate the application of this technology in cancer therapeutics through non-thermal, minimally scarring tumor ablation.
Keywords :
bioelectric phenomena; biological effects of fields; biomembranes; cancer; cellular biophysics; lipid bilayers; molecular dynamics method; nanobiotechnology; patient treatment; tumours; water; biophysical phenomena; cancer therapeutics; cell membranes; conductive pores; depolarize mitochondrial membranes; electric field-driven reorganization; intracellular calcium release; membrane-spanning water bridges; microsecond pulsed electric field interactions; minimally scarring tumor ablation; molecular simulation; nanosecond pulsed electric field interactions; phospholipid bilayers; phospholipid head groups; skin cancer; water molecules; Biomembranes; Calcium; Educational institutions; Electric fields; Electrical engineering; Lesions; Viterbi algorithm;
Conference_Titel :
General Assembly and Scientific Symposium, 2011 XXXth URSI
Conference_Location :
Istanbul
Print_ISBN :
978-1-4244-5117-3
DOI :
10.1109/URSIGASS.2011.6051308
