Low-Power Fully Integrated 256-Channel Nanowire Electrode-on-Chip Neural Interface for Intracellular Electrophysiology.

Jun Wang, Ren Liu, Youngbin Tchoe, Alessio Paolo Buccino, Akshay Paul, Deborah Pre, Agnieszka D'Antonio-Chronowska, Frazer A Kelly, Anne G Bang, Chul Kim, Shadi Dayeh, Gert Cauwenberghs
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Abstract

Intracellular electrophysiology, a vital and versatile technique in cellular neuroscience, is typically conducted using the patch-clamp method. Despite its effectiveness, this method poses challenges due to its complexity and low throughput. The pursuit of multi-channel parallel neural intracellular recording has been a long-standing goal, yet achieving reliable and consistent scaling has been elusive because of several technological barriers. In this work, we introduce a micropower integrated circuit, optimized for scalable, high-throughput in vitro intrinsically intracellular electrophysiology. This system is capable of simultaneous recording and stimulation, implementing all essential functions such as signal amplification, acquisition, and control, with a direct interface to electrodes integrated on the chip. The electrophysiology system-on-chip (eSoC), fabricated in 180nm CMOS, measures 2.236 mm × 2.236 mm. It contains four 8 × 8 arrays of nanowire electrodes, each with a 50 μm pitch, placed over the top-metal layer on the chip surface, totaling 256 channels. Each channel has a power consumption of 0.47 μW, suitable for current stimulation and voltage recording, and covers 80 dB adjustable range at a sampling rate of 25 kHz. Experimental recordings with the eSoC from cultured neurons in vitro validate its functionality in accurately resolving chemically induced multi-unit intracellular electrical activity.

用于细胞内电生理学的低功耗全集成 256 通道纳米线片上电极神经接口。
细胞内电生理学是细胞神经科学中一项重要的多功能技术,通常采用膜片钳法进行研究。尽管这种方法非常有效,但由于其复杂性和低通量,也带来了挑战。追求多通道并行神经细胞内记录是一个长期目标,但由于一些技术障碍,实现可靠和一致的扩展一直难以实现。在这项工作中,我们介绍了一种微功率集成电路,它针对可扩展、高通量的体外细胞内电生理学进行了优化。该系统能够同时进行记录和刺激,实现信号放大、采集和控制等所有基本功能,并具有与集成在芯片上的电极的直接接口。电生理学片上系统(eSoC)采用 180 纳米 CMOS 制造,尺寸为 2.236 毫米 × 2.236 毫米。它包含四个 8 × 8 的纳米线电极阵列,每个阵列的间距为 50 μm,放置在芯片表面的顶层金属层上,共有 256 个通道。每个通道的功耗为 0.47 μW,适用于电流刺激和电压记录,采样率为 25 kHz,可调范围为 80 dB。使用 eSoC 对体外培养的神经元进行的实验记录验证了它在精确分辨化学诱导的多单元细胞内电活动方面的功能。
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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