Improving non-invasive trajectory decoding via neural correlates of continuous erroneous feedback processing.

Hannah S Pulferer, Kyriaki Kostoglou, Gernot R Müller-Putz
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Abstract

Objective. Over the last decades, error-related potentials (ErrPs) have repeatedly proven especially useful as corrective mechanisms in invasive and non-invasive brain-computer interfaces (BCIs). However, research in this context exclusively investigated the distinction of discrete events intocorrectorerroneousto the present day. Due to this predominant formulation as a binary classification problem, classical ErrP-based BCIs fail to monitor tasks demanding quantitative information on error severity rather than mere qualitative decisions on error occurrence. As a result, fine-tuned and natural feedback control based on continuously perceived deviations from an intended target remains beyond the capabilities of previously used BCI setups.Approach.To address this issue for future BCI designs, we investigated the feasibility of regressing rather than classifying error-related activity non-invasively from the brain.Main results.Using pre-recorded data from ten able-bodied participants in three sessions each and a multi-output convolutional neural network, we demonstrated the above-chance regression of ongoing target-feedback discrepancies from brain signals in a pseudo-online fashion. In a second step, we used this inferred information about the target deviation to correct the initially displayed feedback accordingly, reporting significant improvements in correlations between corrected feedback and target trajectories across feedback conditions.Significance.Our results indicate that continuous information on target-feedback discrepancies can be successfully regressed from cortical activity, paving the way to increasingly naturalistic, fine-tuned correction mechanisms for future BCI applications.

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通过连续错误反馈处理的神经相关性改进非侵入式轨迹解码
目的:在过去几十年中,错误相关电位(ErrPs)多次被证明是有创和无创脑机接口(BCIs)中特别有用的纠正机制。然而,迄今为止,这方面的研究都只研究如何将离散事件区分为正确或错误。由于这种二元分类问题的主要表述方式,基于 ErrP 的经典 BCI 无法监控需要错误严重性定量信息的任务,而不仅仅是错误发生的定性决策。因此,基于持续感知到的与预期目标的偏差而进行的微调和自然反馈控制仍然超出了之前使用的 BCI 设置的能力范围:方法:为解决未来 BCI 设计中的这一问题,我们研究了从大脑非侵入性回归而非分类错误相关活动的可行性:主要结果:通过使用预先录制的十名健全参与者的数据(每人三次)和一个多输出卷积神经网络,我们以一种伪在线方式证明了从大脑信号中回归当前目标反馈差异的可能性。第二步,我们利用这些推断出的目标偏差信息对最初显示的反馈进行了相应的修正,结果表明,在各种反馈条件下,修正后的反馈与目标轨迹之间的相关性有了显著提高:我们的研究结果表明,目标反馈差异的连续信息可以成功地从大脑皮层活动中回归出来,从而为未来 BCI 应用中越来越自然的微调校正机制铺平了道路。
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