Avoiding neuromuscular stimulation in liver irreversible electroporation using radiofrequency electric fields

Quim Castellví, Borja Mercadal, Xavier Moll, Dolors Fondevila, Anna Andaluz, Antoni Ivorra

Research output: Contribution to journalArticleResearchpeer-review

4 Citations (Scopus)

Abstract

© 2018 Institute of Physics and Engineering in Medicine. Electroporation-based treatments typically consist of the application of high-voltage dc pulses. As an undesired side effect, these dc pulses cause electrical stimulation of excitable tissues such as motor nerves. The present in vivo study explores the use of bursts of sinusoidal voltage in a frequency range from 50 kHz to 2 MHz, to induce irreversible electroporation (IRE) whilst avoiding neuromuscular stimulation. A series of 100 dc pulses or sinusoidal bursts, both with an individual duration of 100, were delivered to rabbit liver through thin needles in a monopolar electrode configuration, and thoracic movements were recorded with an accelerometer. Tissue samples were harvested three hours after treatment and later post-processed to determine the dimensions of the IRE lesions. Thermal damage due to Joule heating was ruled out via computer simulations. Sinusoidal bursts with a frequency equal to or above 100 kHz did not cause thoracic movements and induced lesions equivalent to those obtained with conventional dc pulses when the applied voltage amplitude was sufficiently high. IRE efficacy dropped with increasing frequency. For 100 kHz bursts, it was estimated that the electric field threshold for IRE is about 1.4 kV cm-1 whereas that of dc pulses is about 0.5 kV cm-1.
Original languageEnglish
Article number035027
JournalPhysics in Medicine and Biology
Volume63
DOIs
Publication statusPublished - 1 Feb 2018

Keywords

  • ablation
  • electroporation
  • irreversible electroporation
  • radiofrequency electric fields
  • sinusoidal voltages

Fingerprint Dive into the research topics of 'Avoiding neuromuscular stimulation in liver irreversible electroporation using radiofrequency electric fields'. Together they form a unique fingerprint.

Cite this