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Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes.

Publication ,  Journal Article
Howell, B; Huynh, B; Grill, WM
Published in: Journal of neural engineering
August 2015

Deep brain stimulation (DBS) is an effective treatment for movement disorders and a promising therapy for treating epilepsy and psychiatric disorders. Despite its clinical success, the efficiency and selectivity of DBS can be improved. Our objective was to design electrode geometries that increased the efficiency and selectivity of DBS.We coupled computational models of electrodes in brain tissue with cable models of axons of passage (AOPs), terminating axons (TAs), and local neurons (LNs); we used engineering optimization to design electrodes for stimulating these neural elements; and the model predictions were tested in vivo.Compared with the standard electrode used in the Medtronic Model 3387 and 3389 arrays, model-optimized electrodes consumed 45-84% less power. Similar gains in selectivity were evident with the optimized electrodes: 50% of parallel AOPs could be activated while reducing activation of perpendicular AOPs from 44 to 48% with the standard electrode to 0-14% with bipolar designs; 50% of perpendicular AOPs could be activated while reducing activation of parallel AOPs from 53 to 55% with the standard electrode to 1-5% with an array of cathodes; and, 50% of TAs could be activated while reducing activation of AOPs from 43 to 100% with the standard electrode to 2-15% with a distal anode. In vivo, both the geometry and polarity of the electrode had a profound impact on the efficiency and selectivity of stimulation.Model-based design is a powerful tool that can be used to improve the efficiency and selectivity of DBS electrodes.

Duke Scholars

Published In

Journal of neural engineering

DOI

EISSN

1741-2552

ISSN

1741-2560

Publication Date

August 2015

Volume

12

Issue

4

Start / End Page

046030

Related Subject Headings

  • Sensitivity and Specificity
  • Reproducibility of Results
  • Models, Neurological
  • Equipment Failure Analysis
  • Equipment Design
  • Electrodes, Implanted
  • Electric Conductivity
  • Deep Brain Stimulation
  • Computer-Aided Design
  • Computer Simulation
 

Citation

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Howell, B., Huynh, B., & Grill, W. M. (2015). Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes. Journal of Neural Engineering, 12(4), 046030. https://doi.org/10.1088/1741-2560/12/4/046030
Howell, Bryan, Brian Huynh, and Warren M. Grill. “Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes.Journal of Neural Engineering 12, no. 4 (August 2015): 046030. https://doi.org/10.1088/1741-2560/12/4/046030.
Howell B, Huynh B, Grill WM. Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes. Journal of neural engineering. 2015 Aug;12(4):046030.
Howell, Bryan, et al. “Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes.Journal of Neural Engineering, vol. 12, no. 4, Aug. 2015, p. 046030. Epmc, doi:10.1088/1741-2560/12/4/046030.
Howell B, Huynh B, Grill WM. Design and in vivo evaluation of more efficient and selective deep brain stimulation electrodes. Journal of neural engineering. 2015 Aug;12(4):046030.
Journal cover image

Published In

Journal of neural engineering

DOI

EISSN

1741-2552

ISSN

1741-2560

Publication Date

August 2015

Volume

12

Issue

4

Start / End Page

046030

Related Subject Headings

  • Sensitivity and Specificity
  • Reproducibility of Results
  • Models, Neurological
  • Equipment Failure Analysis
  • Equipment Design
  • Electrodes, Implanted
  • Electric Conductivity
  • Deep Brain Stimulation
  • Computer-Aided Design
  • Computer Simulation