正弦波探头：一种提高电极寿命的新方法。

The sinusoidal probe: a new approach to improve electrode longevity.

作者信息

Sohal Harbaljit S, Jackson Andrew, Jackson Richard, Clowry Gavin J, Vassilevski Konstantin, O'Neill Anthony, Baker Stuart N

机构信息

Newcastle Movement Lab, Institute of Neuroscience, Newcastle University Newcastle Upon Tyne, UK ; School of Electrical and Electronic Engineering, Newcastle University Newcastle Upon Tyne, UK.

Newcastle Movement Lab, Institute of Neuroscience, Newcastle University Newcastle Upon Tyne, UK.

出版信息

Front Neuroeng. 2014 Apr 29;7:10. doi: 10.3389/fneng.2014.00010. eCollection 2014.

DOI:10.3389/fneng.2014.00010

PMID:24808859

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4010751/

Abstract

Micromotion between the brain and implanted electrodes is a major contributor to the failure of invasive brain-machine interfaces. Movements of the electrode tip cause recording instabilities while spike amplitudes decline over the weeks/months post-implantation due to glial cell activation caused by sustained mechanical trauma. We have designed a sinusoidal probe in order to reduce movement of the recording tip relative to the surrounding neural tissue. The probe was microfabricated from flexible materials and incorporated a sinusoidal shaft to minimize tethering forces and a 3D spheroid tip to anchor the recording site within the brain. Compared to standard microwire electrodes, the signal-to-noise ratio and local field potential power of sinusoidal probe recordings from rabbits was more stable across recording periods up to 678 days. Histological quantification of microglia and astrocytes showed reduced neuronal tissue damage especially for the tip region between 6 and 24 months post-implantation. We suggest that the micromotion-reducing measures incorporated into our design, at least partially, decreased the magnitude of gliosis, resulting in enhanced longevity of recording.

摘要

大脑与植入电极之间的微动是侵入性脑机接口失效的主要原因。电极尖端的运动会导致记录不稳定，而由于持续机械创伤引起的胶质细胞激活，在植入后的数周/数月内，尖峰幅度会下降。我们设计了一种正弦探针，以减少记录尖端相对于周围神经组织的移动。该探针由柔性材料微制造而成，包含一个正弦轴以最小化系留力，以及一个三维球体尖端以将记录部位固定在脑内。与标准微丝电极相比，在长达678天的记录期内，来自兔子的正弦探针记录的信噪比和局部场电位功率在整个记录过程中更加稳定。小胶质细胞和星形胶质细胞的组织学定量分析表明，神经元组织损伤减少，尤其是在植入后6至24个月的尖端区域。我们认为，我们设计中采用的减少微动的措施至少部分地降低了胶质增生的程度，从而延长了记录寿命。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e02e/4010751/f6d8222b0ab4/fneng-07-00010-g001.jpg

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PLoS One. 2013;8(2):e56673. doi: 10.1371/journal.pone.0056673. Epub 2013 Feb 19.

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Lancet. 2013 Feb 16;381(9866):557-64. doi: 10.1016/S0140-6736(12)61816-9. Epub 2012 Dec 17.

Application of an optogenetic byway for perturbing neuronal activity via glial photostimulation.

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正弦波探头：一种提高电极寿命的新方法。

The sinusoidal probe: a new approach to improve electrode longevity.

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