NeuroBus - Architecture for an Ultra-Flexible Neural Interface

IEEE transactions on biomedical circuits and systems Pub Date : 2024-01-16 DOI:10.1109/TBCAS.2024.3354785

Markus Sporer;Ioana-Georgiana Vasilaş;Ahmed Adžemović;Nicolas Graber;Stefan Reich;Calogero Gueli;Max Eickenscheidt;Ilka Diester;Thomas Stieglitz;Maurits Ortmanns

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Abstract

This article presents the system architecture for an implant concept called NeuroBus . Tiny distributed direct digitizing neural recorder ASICs on an ultra-flexible polyimide substrate are connected in a bus-like structure, allowing short connections between electrode and recording front-end with low wiring effort and high customizability. The small size (344

$\,\mu$

m × 294

$\mu$

m) of the ASICs and the ultraflexible substrate allow a low bending stiffness, enabling the implant to adapt to the curvature of the brain and achieving high structural biocompatibility. We introduce the architecture, the integrated building blocks, and the post-CMOS processes required to realize a NeuroBus , and we characterize the prototyped direct digitizing neural recorder front-end as well as polyimide-based ECoG brain interface. A rodent animal model is further used to validate the joint capability of the recording front-end and thin-film electrode array.

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NeuroBus - 超灵活神经接口架构。

本文介绍了一种名为 "神经总线"（NeuroBus）的植入概念的系统架构。微小的分布式直接数字化神经记录器 ASIC 位于超柔性聚酰亚胺基底上，以总线式结构连接，从而实现了电极和记录前端之间的短连接，布线工作量低，可定制性高。ASIC 的小尺寸（344 μm x 294 μm）和超柔性基底允许较低的弯曲刚度，从而使植入体能够适应大脑的弧度，实现较高的结构生物相容性。我们介绍了实现神经总线所需的架构、集成构件和后 CMOS 工艺，并对直接数字化神经记录器前端原型以及基于聚酰亚胺的心电图脑接口进行了表征。我们进一步利用啮齿动物模型来验证记录前端和薄膜电极阵列的联合能力。

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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IEEE transactions on biomedical circuits and systems

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