P.077 Reducing artifact during in bi-directional brain interfacing

K. Tourigny, T. Denison
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Abstract

Background: Bi-directional brain interfacing (closed loop DBS) is a modern focus of neuroengineering research. Most current clinical systems are open loop, allowing one way communication from the IPG battery to the brain. Bi-directional systems allow both stimulation and recording of neural activity (local field potential, LFP). The system algorithm can measure known pathologic LFPs to guide change in stimulation. However, recording LFPs from the brain encounters electrical artifact from the heart. Reducing artifact is imperative to accurate measurement of neural activity. Artifact will cause the bi-directional system to miscalculate stimulation parameters. This project evaluated reduction of artifact by moving the IPG further away from the heart in a device implanted into the skull. Methods: LFP data from ongoing clinical trials was collected and analysed for artifact using open source code. Anatomic targets include STN, PPN, CMT, and PAG. Results: Cardiac artifact is reduced in skull mounted DBS as shown by power spectral density of LFPs in each region. Conclusions: This project shows the importance of surgical placement of DBS sensing devices to reduce cardiac artifact in bi-directional brain interfacing. This has important engineering and surgical design implications for safety and performance as the field of closed loop DBS transitions from research to clinical settings.
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P.077 减少双向脑接口过程中的伪影
背景:双向脑接口(闭环 DBS)是现代神经工程研究的重点。目前大多数临床系统都是开环系统,允许从 IPG 电池到大脑进行单向通信。双向系统可同时刺激和记录神经活动(局部场电位,LFP)。系统算法可以测量已知的病理 LFP,从而指导刺激的改变。然而,从大脑记录 LFP 会遇到来自心脏的电伪影。要准确测量神经活动,必须减少伪差。伪影会导致双向系统错误计算刺激参数。该项目评估了通过将植入颅骨的设备中的 IPG 移到离心脏更远的位置来减少伪影的情况。方法:从正在进行的临床试验中收集 LFP 数据,并使用开放源代码对伪影进行分析。解剖目标包括 STN、PPN、CMT 和 PAG。结果:各区域 LFP 的功率谱密度显示,安装在头骨上的 DBS 可减少心脏伪影。结论:该项目显示了手术放置 DBS 传感设备以减少双向脑接口中心脏伪影的重要性。随着闭环 DBS 领域从研究向临床过渡,这对安全性和性能具有重要的工程和手术设计意义。
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