Chronic stability of a neuroprosthesis comprising multiple adjacent Utah arrays in monkeys.

IF 3.7 3区 医学 Q2 ENGINEERING, BIOMEDICAL Journal of neural engineering Pub Date : 2023-06-30 DOI:10.1088/1741-2552/ace07e
Xing Chen, Feng Wang, Roxana Kooijmans, Peter Christiaan Klink, Christian Boehler, Maria Asplund, Pieter Roelf Roelfsema
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Abstract

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 × 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 IrOxcoating 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.

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猴子体内由多个相邻犹他阵列组成的神经假体的长期稳定性。
目的。通过神经假体对视觉皮层进行电刺激,可诱导对光点("phosphenes")的感知,即使失明数十年后仍有可能识别简单的形状。然而,恢复功能性视觉需要大量电极,而临床上在视觉皮层内长期植入皮层内电极只能使用多达 96 个通道的设备。方法:我们在两只视力正常的猕猴的初级视皮层(V1)和第4视区(V4)植入了16个微电极阵列(犹他阵列),这些阵列由8 × 8个电极组成,电极尖端带有氧化铱。我们监测动物的健康状况,并通过计算视觉驱动神经元活动的信噪比、动作电位波形的峰峰值电压以及高振幅信号通道的数量来测量电极阻抗和神经元信号质量。我们对大脑皮层进行微刺激,确定可感知的最小电流,监测成功产生幻视的通道数量。我们还考察了植入 2-3 年后植入物对视觉任务的影响,并在植入 3-3.5 年后通过组织学分析确定了脑组织的完整性。在整个植入期间,猴子都保持健康,装置保持了机械完整性和导电性。然而,我们观察到信号质量随着时间的推移而下降,磷光体诱发电极的数量减少,电极阻抗下降,在与植入皮质区域相对应的视野位置的视觉任务中表现受损。两只动物中有一只的电流阈值随着时间的推移而升高。组织学分析显示阵列被包裹,皮质退化。对一个阵列进行的扫描电子显微镜检查发现,IrOx 涂层出现降解,尖端破损的电极阻抗更高。在 NHP 视觉皮层中长期植入高通道数装置会导致皮层组织变形,刺激效果和信号质量随时间下降。我们的结论是,在未来临床应用之前,需要改善设备的生物相容性和/或改进植入技术。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of neural engineering
Journal of neural engineering 工程技术-工程:生物医学
CiteScore
7.80
自引率
12.50%
发文量
319
审稿时长
4.2 months
期刊介绍: The goal of Journal of Neural Engineering (JNE) is to act as a forum for the interdisciplinary field of neural engineering where neuroscientists, neurobiologists and engineers can publish their work in one periodical that bridges the gap between neuroscience and engineering. The journal publishes articles in the field of neural engineering at the molecular, cellular and systems levels. The scope of the journal encompasses experimental, computational, theoretical, clinical and applied aspects of: Innovative neurotechnology; Brain-machine (computer) interface; Neural interfacing; Bioelectronic medicines; Neuromodulation; Neural prostheses; Neural control; Neuro-rehabilitation; Neurorobotics; Optical neural engineering; Neural circuits: artificial & biological; Neuromorphic engineering; Neural tissue regeneration; Neural signal processing; Theoretical and computational neuroscience; Systems neuroscience; Translational neuroscience; Neuroimaging.
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