A Nanowell-based MoS Neuroelectrode for High-sensitivity Neural Recording

Overview

Journal iScience

Publisher Cell Press

Date 2024 Oct 11

PMID 39391733

Authors

Shuangjie Liu

Xinyu Sun

Yang Wang

Kaijin Liu

Renpeng Liu

Yuqin Zhang

Zhaoliang Ni

Wanyu Tang

Shaofang Zhang

Xiaoyu Mu

Hao Wang

Xiao-Dong Zhang

Dong Ming

Affiliations

Soon will be listed here.

Abstract

Implantable neural electrodes are crucial in neurological diagnosis and therapy because of their ultra-high spatial resolution, but they are constrained by high impedance and insufficient charge injection capacity, resulting in noise that often obscures valuable signals. Emerging nanotechnologies are powerful tools to improve sensitivity and biocompatibility. Herein, we developed quantized 2D MoS electrodes by incorporating bioactive MoS nanosheets onto bare electrodes, achieving sensitive, compatible recording. The 2D materials can create tiny nanowells, which behaved as quantized charge storage units and thus improved sensitivity. The key sensitivity indicators, impedance and cathode charge storage capacity, showed a multifold increase. The 17.7-fold improvement in catalytic activity of MoS electrodes facilitated effective current transmission and reduced inflammatory response. recording showed that the sensitivity of local field potentials increased throughout frequency range and peaked at a 4.7-fold in β rhythm. This work provides a general strategy for achieving effective diagnoses of neurological disorders.

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