Frontiers in Neurology (Oct 2021)

Prediction of Clinical Deep Brain Stimulation Target for Essential Tremor From 1.5 Tesla MRI Anatomical Landmarks

  • Julien Engelhardt,
  • Julien Engelhardt,
  • Emmanuel Cuny,
  • Emmanuel Cuny,
  • Dominique Guehl,
  • Dominique Guehl,
  • Pierre Burbaud,
  • Pierre Burbaud,
  • Nathalie Damon-Perrière,
  • Nathalie Damon-Perrière,
  • Camille Dallies-Labourdette,
  • Camille Dallies-Labourdette,
  • Juliette Thomas,
  • Juliette Thomas,
  • Olivier Branchard,
  • Louise-Amélie Schmitt,
  • Narimane Gassa,
  • Nejib Zemzemi,
  • Nejib Zemzemi

DOI
https://doi.org/10.3389/fneur.2021.620360
Journal volume & issue
Vol. 12

Abstract

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Background: Deep brain stimulation is an efficacious treatment for refractory essential tremor, though targeting the intra-thalamic nuclei remains challenging.Objectives: We sought to develop an inverse approach to retrieve the position of the leads in a cohort of patients operated on with optimal clinical outcomes from anatomical landmarks identifiable by 1.5 Tesla magnetic resonance imaging.Methods: The learning database included clinical outcomes and post-operative imaging from which the coordinates of the active contacts and those of anatomical landmarks were extracted. We used machine learning regression methods to build three different prediction models. External validation was performed according to a leave-one-out cross-validation.Results: Fifteen patients (29 leads) were included, with a median tremor improvement of 72% on the Fahn–Tolosa–Marin scale. Kernel ridge regression, deep neural networks, and support vector regression (SVR) were used. SVR gave the best results with a mean error of 1.33 ± 1.64 mm between the predicted target and the active contact position.Conclusion: We report an original method for the targeting in deep brain stimulation for essential tremor based on patients' radio-anatomical features. This approach will be tested in a prospective clinical trial.

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