Continuous vestibular implant stimulation partially restores eye-stabilizing reflexes
Peter J. Boutros, Desi P. Schoo, Mehdi Rahman, Nicolas S. Valentin, Margaret R. Chow, Andrianna I. Ayiotis, Brian J. Morris, Andreas Hofner, Aitor Morillo Rascon, Andreas Marx, Ross Deas, Gene Y. Fridman, Natan S. Davidovics, Bryan K. Ward, Carolina Treviño, Stephen P. Bowditch, Dale C. Roberts, Kelly E. Lane, Yoav Gimmon, Michael C. Schubert, John P. Carey, Andreas Jaeger, Charles C. Della Santina
Peter J. Boutros, Desi P. Schoo, Mehdi Rahman, Nicolas S. Valentin, Margaret R. Chow, Andrianna I. Ayiotis, Brian J. Morris, Andreas Hofner, Aitor Morillo Rascon, Andreas Marx, Ross Deas, Gene Y. Fridman, Natan S. Davidovics, Bryan K. Ward, Carolina Treviño, Stephen P. Bowditch, Dale C. Roberts, Kelly E. Lane, Yoav Gimmon, Michael C. Schubert, John P. Carey, Andreas Jaeger, Charles C. Della Santina
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Clinical Research and Public Health Neuroscience Otology

Continuous vestibular implant stimulation partially restores eye-stabilizing reflexes

Abstract

BACKGROUND Bilateral loss of vestibular (inner ear inertial) sensation causes chronically blurred vision during head movement, postural instability, and increased fall risk. Individuals who fail to compensate despite rehabilitation therapy have no adequate treatment options. Analogous to hearing restoration via cochlear implants, prosthetic electrical stimulation of vestibular nerve branches to encode head motion has garnered interest as a potential treatment, but prior studies in humans have not included continuous long-term stimulation or 3D binocular vestibulo-ocular reflex (VOR) oculography, without which one cannot determine whether an implant selectively stimulates the implanted ear’s 3 semicircular canals.METHODS We report binocular 3D VOR responses of 4 human subjects with ototoxic bilateral vestibular loss unilaterally implanted with a Labyrinth Devices Multichannel Vestibular Implant System vestibular implant, which provides continuous, long-term, motion-modulated prosthetic stimulation via electrodes in 3 semicircular canals.RESULTS Initiation of prosthetic stimulation evoked nystagmus that decayed within 30 minutes. Stimulation targeting 1 canal produced 3D VOR responses approximately aligned with that canal’s anatomic axis. Targeting multiple canals yielded responses aligned with a vector sum of individual responses. Over 350–812 days of continuous 24 h/d use, modulated electrical stimulation produced stable VOR responses that grew with stimulus intensity and aligned approximately with any specified 3D head rotation axis.CONCLUSION These results demonstrate that a vestibular implant can selectively, continuously, and chronically provide artificial sensory input to all 3 implanted semicircular canals in individuals disabled by bilateral vestibular loss, driving reflexive VOR eye movements that approximately align in 3D with the head motion axis encoded by the implant.TRIAL REGISTRATION ClinicalTrials.gov: NCT02725463.FUNDING NIH/National Institute on Deafness and Other Communication Disorders: R01DC013536 and 2T32DC000023; Labyrinth Devices, LLC; and Med-El GmbH.

Authors

Peter J. Boutros, Desi P. Schoo, Mehdi Rahman, Nicolas S. Valentin, Margaret R. Chow, Andrianna I. Ayiotis, Brian J. Morris, Andreas Hofner, Aitor Morillo Rascon, Andreas Marx, Ross Deas, Gene Y. Fridman, Natan S. Davidovics, Bryan K. Ward, Carolina Treviño, Stephen P. Bowditch, Dale C. Roberts, Kelly E. Lane, Yoav Gimmon, Michael C. Schubert, John P. Carey, Andreas Jaeger, Charles C. Della Santina

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Figure 3

MVI stimulation evokes 3D VOR responses align with targeted semicircular canal.

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MVI stimulation evokes 3D VOR responses align with targeted semicircular...
Mean ± SD cycle-averaged binocular 3D VOR eye velocity responses of subject MVI002 during n cycles of 2 Hz, 40% duty cycle, square-wave-modulated (200 pulses/s for 200 ms, 300 ms off), biphasic, charge-balanced 100 μs/phase current pulse trains. (A) Stimulation via electrode E3 in LP canal ampulla with pulses of 300–599 μA. (B) Stimulation via electrode E6 in LH canal with pulses of 50–448 μA produces a rightward slow phase eye velocity (negative by convention). (C) Stimulation via electrode E9 in LA canal with pulses of 151–448 μA. Right eye response for 396 μA stimulus is missing due to video-oculography tracking failure. (D) Dashed lines denote anatomic semicircular canal axes. Solid vectors depict mean rotation axis for each eye during peak excitatory slow phase response eye velocity for electrodes and currents in adjacent legends. Conic sections denote VOR variability via eigenvalue decomposition of the 3D angular velocity covariance matrix. (E) Canal axes relative to skull landmarks. (F) Same data as D but viewed from above (i.e., from +z/LHRH axis).