无需机器学习从脑电数据中提取连续睡眠深度

Q2 Medicine
Claus Metzner , Achim Schilling , Maximilian Traxdorf , Holger Schulze , Konstantin Tziridis , Patrick Krauss
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引用次数: 4

摘要

人类的睡眠周期被划分为离散的睡眠阶段,这些阶段可以通过受过训练的专家或机器学习系统在脑电图(EEG)和其他生物信号中识别。然而,目前尚不清楚这些人为定义的阶段是否可以通过无监督的数据分析方法重新发现,只使用最少量的通用预处理。基于睡眠中的受试者夜间记录的脑电图数据,我们使用一般判别值作为类别可分性的定量测量来研究睡眠阶段的聚类程度。在原始数据中几乎没有发现聚类,即使在将每个30秒时期的EEG信号从时域转换到信息更丰富的频域之后也是如此。然而,对这些历元频谱的主成分分析(PCA)表明,睡眠阶段在某些PCA成分的低维子空间中分离得明显更好。特别是分量C1(t)可以作为一个稳健、连续的“主变量”,对睡眠深度进行编码,因此与“睡眠图”(离散睡眠阶段随时间变化的常见图)密切相关。此外,C1(t)在睡眠阶段恒定的延长时间段内显示出持续的趋势,这表明睡眠可以更好地理解为一个连续体。C1(t)的这些有趣特性不仅与理解睡眠期间的大脑动力学有关,而且可能被用于私人和临床使用的低成本单通道睡眠跟踪设备。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Extracting continuous sleep depth from EEG data without machine learning

Extracting continuous sleep depth from EEG data without machine learning

Extracting continuous sleep depth from EEG data without machine learning

Extracting continuous sleep depth from EEG data without machine learning

The human sleep-cycle has been divided into discrete sleep stages that can be recognized in electroencephalographic (EEG) and other bio-signals by trained specialists or machine learning systems. It is however unclear whether these human-defined stages can be re-discovered with unsupervised methods of data analysis, using only a minimal amount of generic pre-processing. Based on EEG data, recorded overnight from sleeping human subjects, we investigate the degree of clustering of the sleep stages using the General Discrimination Value as a quantitative measure of class separability. Virtually no clustering is found in the raw data, even after transforming the EEG signals of each 30-s epoch from the time domain into the more informative frequency domain. However, a Principal Component Analysis (PCA) of these epoch-wise frequency spectra reveals that the sleep stages separate significantly better in the low-dimensional sub-space of certain PCA components. In particular the component C1(t) can serve as a robust, continuous ‘master variable’ that encodes the depth of sleep and therefore correlates strongly with the ‘hypnogram’, a common plot of the discrete sleep stages over time. Moreover, C1(t) shows persistent trends during extended time periods where the sleep stage is constant, suggesting that sleep may be better understood as a continuum. These intriguing properties of C1(t) are not only relevant for understanding brain dynamics during sleep, but might also be exploited in low-cost single-channel sleep tracking devices for private and clinical use.

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来源期刊
Neurobiology of Sleep and Circadian Rhythms
Neurobiology of Sleep and Circadian Rhythms Neuroscience-Behavioral Neuroscience
CiteScore
4.50
自引率
0.00%
发文量
9
审稿时长
69 days
期刊介绍: Neurobiology of Sleep and Circadian Rhythms is a multidisciplinary journal for the publication of original research and review articles on basic and translational research into sleep and circadian rhythms. The journal focuses on topics covering the mechanisms of sleep/wake and circadian regulation from molecular to systems level, and on the functional consequences of sleep and circadian disruption. A key aim of the journal is the translation of basic research findings to understand and treat sleep and circadian disorders. Topics include, but are not limited to: Basic and translational research, Molecular mechanisms, Genetics and epigenetics, Inflammation and immunology, Memory and learning, Neurological and neurodegenerative diseases, Neuropsychopharmacology and neuroendocrinology, Behavioral sleep and circadian disorders, Shiftwork, Social jetlag.
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