Institute of Medical Psychology and Behavioral Neurobiology, University of Tübingen, Tübingen, Germany.
Graduate Training Centre of Neuroscience/IMPRS for Cognitive & Systems Neuroscience, University of Tübingen, Tübingen, Germany.
Sleep. 2021 Aug 13;44(8). doi: 10.1093/sleep/zsab056.
The brain appears to use internal models to successfully interact with its environment via active predictions of future events. Both internal models and the predictions derived from them are based on previous experience. However, it remains unclear how previously encoded information is maintained to support this function, especially in the visual domain. In the present study, we hypothesized that sleep consolidates newly encoded spatio-temporal regularities to improve predictions afterwards.
We tested this hypothesis using a novel sequence-learning paradigm that aimed to dissociate perceptual from motor learning. We recorded behavioral performance and high-density electroencephalography (EEG) in male human participants during initial training and during testing two days later, following an experimental night of sleep (n = 16, including high-density EEG recordings) or wakefulness (n = 17).
Our results show sleep-dependent behavioral improvements correlated with sleep-spindle activity specifically over occipital cortices. Moreover, event-related potential (ERP) responses indicate a shift of attention away from predictable to unpredictable sequences after sleep, consistent with enhanced automaticity in the processing of predictable sequences.
These findings suggest a sleep-dependent improvement in the prediction of visual sequences, likely related to visual cortex reactivation during sleep spindles. Considering that controls in our experiments did not fully exclude oculomotor contributions, future studies will need to address the extent to which these effects depend on purely perceptual versus oculomotor sequence learning.
大脑似乎通过对未来事件的主动预测,利用内部模型成功地与环境进行互动。内部模型及其衍生的预测都是基于以前的经验。然而,目前尚不清楚如何保持以前编码的信息以支持此功能,尤其是在视觉领域。在本研究中,我们假设睡眠可以巩固新编码的时空规律,从而提高后续的预测能力。
我们使用一种新的序列学习范式来检验这一假设,该范式旨在将感知与运动学习区分开来。我们在男性参与者进行初始训练和两天后的测试期间记录了行为表现和高密度脑电图(EEG),其中包括实验之夜的睡眠(n=16,包括高密度 EEG 记录)或清醒(n=17)。
我们的结果表明,睡眠依赖性的行为改善与睡眠纺锤波活动相关,特别是在枕叶皮层。此外,事件相关电位(ERP)反应表明,睡眠后注意力从可预测序列转移到不可预测序列,这与可预测序列处理的自动性增强一致。
这些发现表明,视觉序列的预测能力在睡眠后得到了改善,这可能与睡眠纺锤波期间视觉皮层的再激活有关。考虑到我们实验中的对照组并不能完全排除眼动的贡献,未来的研究将需要解决这些效应在多大程度上取决于纯粹的感知序列学习或眼动序列学习。
