Journal of Medical Radiation Sciences (Sep 2024)

Safety of intracranial electrodes in an MRI environment: a technical report

  • Yarema B. Bezchlibnyk,
  • Rolando Quiles,
  • Jeremy Barber,
  • Benjamin Osa,
  • Keven Clifford,
  • Ryan Murtaugh

DOI
https://doi.org/10.1002/jmrs.775
Journal volume & issue
Vol. 71, no. 3
pp. 461 – 473

Abstract

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Abstract Introduction Intracranial electroencephalography (iEEG) involves placing intracranial electrodes to localise seizures in patients with medically refractory epilepsy. While magnetic resonance imaging (MRI) enables visualisation of electrodes within patient‐specific anatomy, the safety of these electrodes must be confirmed prior to routine clinical utilisation. Therefore, the purpose of this study was to evaluate the safety of iEEG electrodes from a particular manufacturer in a 3.0‐Tesla (3.0T) MRI environment. Methods Measurements of magnetically induced displacement force and torque were determined for each of the 10 test articles using standardised techniques. Test articles were subsequently evaluated for radiofrequency‐induced heating using a Perspex phantom in both open and ‘fault’ conditions. Additionally, we assessed radiofrequency (RF)‐induced heating with all test articles placed into the phantom simultaneously to simulate an implantation, again in both open and ‘fault’ conditions. Finally, each test article was evaluated for MRI artefacts. Results The magnetically induced displacement force was found to be less than the force on the article due to gravity for all test articles. Similarly, the maximum magnetically induced torque was less than the worst‐case torque due to gravity for all test articles apart from the 8‐contact strip – for which it was 11% greater – and the depthalon cap. The maximum temperature change for any portion of any test article assessed individually was 1.7°C, or 1.2°C for any device component meant to be implanted intracranially. In the implantation configuration, the maximum recorded temperature change was 0.7°C. Conclusions MRI may be safely performed for localising iEEG electrodes at 3.0T under certain conditions.

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