Chronic stability of a neuroprosthesis comprising multiple adjacent Utah arrays in monkeys
Journal article, 2023

Objective. Electrical stimulation of visual cortex via a neuroprosthesis induces the perception of dots of light ('phosphenes'), potentially allowing recognition of simple shapes even after decades of blindness. However, restoration of functional vision requires large numbers of electrodes, and chronic, clinical implantation of intracortical electrodes in the visual cortex has only been achieved using devices of up to 96 channels. We evaluated the efficacy and stability of a 1024-channel neuroprosthesis system in non-human primates (NHPs) over more than 3 years to assess its suitability for long-term vision restoration. Approach. We implanted 16 microelectrode arrays (Utah arrays) consisting of 8 x 8 electrodes with iridium oxide tips in the primary visual cortex (V1) and visual area 4 (V4) of two sighted macaques. We monitored the animals' health and measured electrode impedances and neuronal signal quality by calculating signal-to-noise ratios of visually driven neuronal activity, peak-to-peak voltages of the waveforms of action potentials, and the number of channels with high-amplitude signals. We delivered cortical microstimulation and determined the minimum current that could be perceived, monitoring the number of channels that successfully yielded phosphenes. We also examined the influence of the implant on a visual task after 2-3 years of implantation and determined the integrity of the brain tissue with a histological analysis 3-3.5 years post-implantation. Main results. The monkeys remained healthy throughout the implantation period and the device retained its mechanical integrity and electrical conductivity. However, we observed decreasing signal quality with time, declining numbers of phosphene-evoking electrodes, decreases in electrode impedances, and impaired performance on a visual task at visual field locations corresponding to implanted cortical regions. Current thresholds increased with time in one of the two animals. The histological analysis revealed encapsulation of arrays and cortical degeneration. Scanning electron microscopy on one array revealed degradation of IrOx coating and higher impedances for electrodes with broken tips. Significance. Long-term implantation of a high-channel-count device in NHP visual cortex was accompanied by deformation of cortical tissue and decreased stimulation efficacy and signal quality over time. We conclude that improvements in device biocompatibility and/or refinement of implantation techniques are needed before future clinical use is feasible.

V4

microstimulation

blindness

Utah arrays

V1

neuroprosthesis

non-human primate

Author

Xing Chen

Netherlands Institute for Neuroscience NIN - KNAW

University of Pittsburgh

Feng Wang

Netherlands Institute for Neuroscience NIN - KNAW

Roxana Kooijmans

Netherlands Institute for Neuroscience NIN - KNAW

Peter Christiaan Klink

Netherlands Institute for Neuroscience NIN - KNAW

Utrecht University

Sorbonne University

Christian Boehler

University of Freiburg

Maria Asplund

University of Freiburg

Chalmers, Microtechnology and Nanoscience (MC2), Electronics Material and Systems

Pieter Roelf Roelfsema

Netherlands Institute for Neuroscience NIN - KNAW

Vrije Universiteit Amsterdam

Sorbonne University

Academic Medical Centre (AMC)

Journal of Neural Engineering

1741-2560 (ISSN) 17412552 (eISSN)

Vol. 20 3 036039

Subject Categories

Neurosciences

Biomaterials Science

DOI

10.1088/1741-2552/ace07e

PubMed

37386891

More information

Latest update

7/14/2023