一种用于在现实环境中持续、实时监测工作记忆负荷的脑机接口。

A brain-computer interface for the continuous, real-time monitoring of working memory load in real-world environments.

作者信息

Mora-Sánchez Aldo, Pulini Alfredo-Aram, Gaume Antoine, Dreyfus Gérard, Vialatte François-Benoît

机构信息

1Brain Plasticity Unit, CNRS, UMR8249, Paris, 75005 France.

2ESPCI Paris, PSL Research University, Paris, 75005 France.

出版信息

Cogn Neurodyn. 2020 Jun;14(3):301-321. doi: 10.1007/s11571-020-09573-x. Epub 2020 Mar 9.

DOI:10.1007/s11571-020-09573-x

PMID:32399073

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7203264/

Abstract

We developed a brain-computer interface (BCI) able to continuously monitor working memory (WM) load in real-time (considering the last 2.5 s of brain activity). The BCI is based on biomarkers derived from spectral properties of non-invasive electroencephalography (EEG), subsequently classified by a linear discriminant analysis classifier. The BCI was trained on a visual WM task, tested in a real-time visual WM task, and further validated in a real-time cross task (mental arithmetic). Throughout each trial of the cross task, subjects were given real or sham feedback about their WM load. At the end of the trial, subjects were asked whether the feedback provided was real or sham. The high rate of correct answers provided by the subjects validated not only the global behaviour of the WM-load feedback, but also its real-time dynamics. On average, subjects were able to provide a correct answer 82% of the time, with one subject having 100% accuracy. Possible cognitive and motor confounding factors were disentangled to support the claim that our EEG-based markers correspond indeed to WM.

摘要

我们开发了一种脑机接口（BCI），它能够实时持续监测工作记忆（WM）负荷（考虑大脑活动的最后2.5秒）。该BCI基于从无创脑电图（EEG）频谱特性得出的生物标志物，随后通过线性判别分析分类器进行分类。该BCI在视觉WM任务上进行训练，在实时视觉WM任务中进行测试，并在实时交叉任务（心算）中进一步验证。在交叉任务的每个试验过程中，会向受试者提供关于其WM负荷的真实或虚假反馈。在试验结束时，询问受试者所提供的反馈是真实的还是虚假的。受试者提供的高正确率不仅验证了WM负荷反馈的整体行为，还验证了其实时动态。平均而言，受试者在82%的时间里能够给出正确答案，其中一名受试者的准确率达到100%。我们梳理了可能的认知和运动混杂因素，以支持我们基于脑电图的标志物确实与工作记忆相对应这一说法。

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