An implantable neuroprocessor for multichannel compressive neural recording and on-the-fly spike sorting with wireless telemetry

2010 Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 2010-11-01 DOI:10.1109/BIOCAS.2010.5709556

Fei Zhang, M. Aghagolzadeh, K. Oweiss

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引用次数: 14

Abstract

In this work, a fully implantable and scalable neuroprocessor has been designed to process neural recordings in awake behaving animals. The neuroprocessor operates at 6.4 MHz to process neural signals from 32 microelectrode channels sampled at 25 KHz and transmits only the critical neural information over a 1 Mbps wireless channel in order to meet the stringent hardware and communication constraints imposed on an implantable device. The neuroprocessor can be programmed to compress neural data using a sparse representation of neural signals via lifting discrete wavelet transform (DWT) and/or perform on-the-fly spike sorting on the compressed data stream if followed by a “smart” thresholding mechanism. This unique feature reduces the overall system latency and permit instantaneous decoding of neural signals to take place in real-time. The neuroprocessor therefore uses the limited telemetry bandwidth more efficiently while preserving important information in the neural data, and hence improves the practicality and viability of implantable microelectrode arrays to accelerate their deployment in clinical applications of brain-machine interfaces.

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一种植入式神经处理器，用于多通道压缩神经记录和无线遥测的动态尖峰排序

在这项工作中，一个完全可植入和可扩展的神经处理器被设计用来处理清醒行为动物的神经记录。该神经处理器的工作频率为6.4 MHz，处理来自32个采样频率为25 KHz的微电极通道的神经信号，并仅通过1 Mbps的无线通道传输关键神经信息，以满足植入式设备严格的硬件和通信限制。神经处理器可以通过编程，通过提升离散小波变换(DWT)使用神经信号的稀疏表示来压缩神经数据，或者在压缩数据流上执行动态尖峰排序(如果遵循“智能”阈值机制)。这种独特的功能减少了整个系统的延迟，并允许实时进行神经信号的瞬时解码。因此，神经处理器更有效地利用有限的遥测带宽，同时保留神经数据中的重要信息，从而提高可植入微电极阵列的实用性和可行性，加速其在脑机接口临床应用中的部署。

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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2010 Biomedical Circuits and Systems Conference (BioCAS)

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