PLoS ONE (Jan 2015)

A New Imaging Platform for Visualizing Biological Effects of Non-Invasive Radiofrequency Electric-Field Cancer Hyperthermia.

  • Stuart J Corr,
  • Sabeel Shamsudeen,
  • Leoncio A Vergara,
  • Jason Chak-Shing Ho,
  • Matthew J Ware,
  • Vazrik Keshishian,
  • Kenji Yokoi,
  • David J Savage,
  • Ismail M Meraz,
  • Warna Kaluarachchi,
  • Brandon T Cisneros,
  • Mustafa Raoof,
  • Duy Trac Nguyen,
  • Yingchun Zhang,
  • Lon J Wilson,
  • Huw Summers,
  • Paul Rees,
  • Steven A Curley,
  • Rita E Serda

DOI
https://doi.org/10.1371/journal.pone.0136382
Journal volume & issue
Vol. 10, no. 8
p. e0136382

Abstract

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Herein, we present a novel imaging platform to study the biological effects of non-invasive radiofrequency (RF) electric field cancer hyperthermia. This system allows for real-time in vivo intravital microscopy (IVM) imaging of radiofrequency-induced biological alterations such as changes in vessel structure and drug perfusion. Our results indicate that the IVM system is able to handle exposure to high-power electric-fields without inducing significant hardware damage or imaging artifacts. Furthermore, short durations of low-power (< 200 W) radiofrequency exposure increased transport and perfusion of fluorescent tracers into the tumors at temperatures below 41°C. Vessel deformations and blood coagulation were seen for tumor temperatures around 44°C. These results highlight the use of our integrated IVM-RF imaging platform as a powerful new tool to visualize the dynamics and interplay between radiofrequency energy and biological tissues, organs, and tumors.