Wireless and Wearable Auditory EEG Acquisition Hardware Using Around-The-Ear cEEGrid Electrodes.

Arthur Van Den Broucke, Joris Van Kerrebrouck, Wannes Van Ransbeeck, Robin Pynckels, Attila Frater, Guy Torfs, Sarah Verhulst
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Abstract

Aside from a clinical interest in electroencephalography (EEG) measurements of real-time data with a high temporal resolution, there is a demand for acquisition systems that are operable outside the laboratory environment. In this study, we designed a wearable and low-power EEG system for multichannel EEG acquisition beyond the lab doors. Around-the-ear cEEGrid electrodes are used to capture 8 biopotential channels which are amplified by low-power precision instrumentation amplifiers and passed on to an analog-to-digital converter (ADC). An ESP32 micro-controller captures the data from the ADC and stores it on an external SD card. The proposed system is compared to a state-of-the-art EEG acquisition system (BioSemi) to assess its diagnostic power for auditory brainstem responses (ABRs). The recordings with our portable system match, and even outperform, the baseline method's specifications. Our hardware opens up new avenues for fast sampling-rate auditory EEG recordings that can be used in hearing diagnostics, damage prevention and treatment follow up.

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使用环耳 cEEGrid 电极的无线可穿戴听觉脑电图采集硬件。
除了临床上对高时间分辨率实时数据的脑电图(EEG)测量感兴趣外,人们还需要可在实验室环境外操作的采集系统。在这项研究中,我们设计了一种可穿戴的低功耗脑电图系统,用于在实验室门外进行多通道脑电图采集。环耳 cEEGrid 电极用于采集 8 个生物电位通道,这些通道由低功耗精密仪器放大器放大,并传输到模数转换器 (ADC)。ESP32 微控制器从模数转换器中捕获数据,并将其存储到外部 SD 卡中。该系统与最先进的脑电图采集系统(BioSemi)进行了比较,以评估其对听性脑干反应(ABR)的诊断能力。使用我们的便携式系统进行的记录符合甚至超过了基准方法的规格。我们的硬件为快速采样率听觉脑电图记录开辟了新途径,可用于听力诊断、损害预防和治疗跟踪。
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