Physiological Artifacts and the Implications for Brain-Machine-Interface Design.

Majid Memarian Sorkhabi, Moaad Benjaber, Peter Brown, Timothy Denison
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引用次数: 12

Abstract

The accurate measurement of brain activity by Brain-Machine-Interfaces (BMI) and closed-loop Deep Brain Stimulators (DBS) is one of the most important steps in communicating between the brain and subsequent processing blocks. In conventional chest-mounted systems, frequently used in DBS, a significant amount of artifact can be induced in the sensing interface, often as a common-mode signal applied between the case and the sensing electrodes. Attenuating this common-mode signal can be a serious challenge in these systems due to finite common-mode-rejection-ratio (CMRR) capability in the interface. Emerging BMI and DBS devices are being developed which can mount on the skull. Mounting the system on the cranial region can potentially suppress these induced physiological signals by limiting the artifact amplitude. In this study, we model the effect of artifacts by focusing on cardiac activity, using a current- source dipole model in a torso-shaped volume conductor. Performing finite element simulation with the different DBS architectures, we estimate the ECG common mode artifacts for several device architectures. Using this model helps define the overall requirements for the total system CMRR to maintain resolution of brain activity. The results of the simulations estimate that the cardiac artifacts for skull-mounted systems will have a significantly lower effect than non-cranial systems that include the pectoral region. It is expected that with a pectoral mounted device, a minimum of 60-80 dB CMRR is required to suppress the ECG artifact, depending on device placement relative to the cardiac dipole, while in cranially mounted devices, a 0 dB CMRR is sufficient, in the worst-case scenario. In addition, the model suggests existing commercial devices could optimize performance with a right-hand side placement. The methods used for estimating cardiac artifacts can be extended to other sources such as motion/muscle sources. The susceptibility of the device to artifacts has significant implications for the practical translation of closed-loop DBS and BMI, including the choice of biomarkers, the system design requirements, and the surgical placement of the device relative to artifact sources.

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生理伪影及其对脑机接口设计的影响。
脑机接口(BMI)和闭环脑深部刺激器(DBS)对脑活动的精确测量是大脑与后续处理模块之间沟通的最重要步骤之一。在DBS中经常使用的传统胸装系统中,在传感接口中可能会产生大量的伪影,通常作为壳体和传感电极之间施加的共模信号。由于接口中的共模抑制比(CMRR)能力有限,在这些系统中,衰减这种共模信号可能是一个严重的挑战。新兴的BMI和DBS装置正在开发中,它们可以安装在头骨上。将系统安装在颅区可以通过限制伪信号的振幅来潜在地抑制这些诱发的生理信号。在这项研究中,我们通过在躯干形状的体积导体中使用电流源偶极子模型,通过关注心脏活动来模拟伪影的影响。对不同DBS结构进行有限元仿真,估计了几种器件结构下的ECG共模伪影。使用该模型有助于定义整个系统CMRR的总体需求,以保持大脑活动的分辨率。模拟结果估计,与包括胸区在内的非颅骨系统相比,颅骨系统的心脏伪影的影响要低得多。根据装置相对于心脏偶极子的放置位置,预计对于胸侧安装的装置,至少需要60-80 dB的CMRR来抑制ECG伪影,而对于颅骨安装的装置,在最坏的情况下,0 dB的CMRR就足够了。此外,该模型表明,现有的商用设备可以通过右侧放置来优化性能。用于估计心脏伪影的方法可以扩展到其他源,如运动/肌肉源。器械对伪影的敏感性对闭环DBS和BMI的实际翻译具有重要意义,包括生物标志物的选择、系统设计要求以及器械相对于伪影源的手术放置。
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