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Flexible Organic Electronic Devices for Pulsed Electric Field Therapy of Glioblastoma

作者: Marie C. Lefevre1, Attila Kaszas1, Gerwin Dijk1,2, Martin Baca1, Olivier Baudino2, Bastien Marchiori2, Loig Kergoat2, David Moreau1, Franck Debarbieux3,4,5, Rodney P. O'Connor1 1Centre CMP, Bioelectronics Department,Mines Saint-Etienne, 2Panaxium SAS, 3Institut Universitaire de France, 4Institut des Neurosciences de la Timone (UMR7289), CNRS,Aix-Marseille Université, 5Centre Européen de Recherche en Imagerie Médicale,Aix-Marseille Université
简介:

Overview

This study presents a protocol for delivering pulsed electric fields using flexible electronics to investigate their therapeutic effects on glioblastoma. The approach integrates various models to visualize the tumor microenvironment and assess the impact of these fields on cancer treatment.

Key Study Components

Area of Science

  • Neuroscience
  • Bioelectronics
  • Cancer Research

Background

  • Flexible interdigitated electrodes are developed for brain tumor models.
  • The method allows for the evaluation of pulsed electric fields on tumors.
  • Different models of increasing complexity are utilized.
  • This research aims to advance precision medicine for cancer treatment.

Purpose of Study

  • To study the therapeutic effects of pulsed electric fields on glioblastoma.
  • To visualize the tumor microenvironment in vivo.
  • To explore the potential of bioelectronics in cancer therapy.

Methods Used

  • Microfabrication techniques for electrode production.
  • In vitro and in vivo models for testing.
  • Imaging techniques to visualize tumor interactions.
  • Protocols for integrating electrodes into biological systems.

Main Results

  • Successful integration of flexible electrodes into tumor models.
  • Demonstrated effects of pulsed electric fields on glioblastoma cells.
  • Potential applications for other cancer types were identified.
  • Manufacturing processes were simplified for broader accessibility.

Conclusions

  • The study provides a novel approach to cancer treatment using bioelectronics.
  • Findings support the use of pulsed electric fields in precision medicine.
  • Future research could expand to other cancer types and applications.

Frequently Asked Questions

What are flexible interdigitated electrodes?
They are specialized electrodes designed for use in various biological models to study electric field effects on cells.
How do pulsed electric fields affect glioblastoma?
Pulsed electric fields can influence tumor cell behavior and potentially enhance therapeutic outcomes.
What models are used in this study?
The study employs in vitro, in ovo, and in vivo murine models to evaluate the effects of the treatment.
Can this method be applied to other cancers?
Yes, the techniques developed may also be applicable to other types of cancers, including patient-derived xenografts.
What is the significance of precision medicine in this research?
Precision medicine aims to tailor treatments to individual patients, improving efficacy and reducing side effects.
What are the manufacturing requirements for the electrodes?
The electrodes can be manufactured using standard microfabrication techniques in a clean room environment.

This work describes the development of flexible interdigitated electrodes for implementation in 3D brain tumor models, namely, in vitro culture, in ovo model, and in vivo murine model. The proposed method can be used to evaluate the effects of pulsed electric fields on tumors at different levels of complexity.

标签: Flexible Organic Electronic Devices,    Pulsed Electric Field Therapy,    Glioblastoma,    Tumor Microenvironment,    Bioelectronics,    Microfabrication Techniques,    Precision Medicine,    Gold Electrode Patterning,    Parylene C Deposition,    Clean Room Fabrication,    Interdigitated Electrode Design,    Negative Photoresist,    Thermal Evaporator,    Chromium Deposition,    Gold Deposition,   
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