Multiscale entropy in a 10-minute vigilance task

IF 2.5 3区心理学 Q3 NEUROSCIENCES International Journal of Psychophysiology Pub Date : 2024-02-28 DOI:10.1016/j.ijpsycho.2024.112323

L. Jack Rhodes , Lorraine Borghetti , Megan B. Morris

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Abstract

Research has shown multiscale entropy, brain signal behavior across time scales, to reliably increase at lower time scales with time-on-task fatigue. However, multiscale entropy has not been examined in short vigilance tasks (i.e., ≤ 10 min). Addressing this gap, we examine multiscale entropy during a 10-minute Psychomotor Vigilance Test (PVT). Thirty-four participants provided neural data while completing the PVT. We compared the first 2 min of the task to the 7th and 8th minutes to avoid end-spurt effects. Results suggested increased multiscale entropy at lower time scales later compared to earlier in the task, suggesting multiscale entropy is a strong marker of time-on-task fatigue onset during short vigils. Separate analyses for Fast and Slow performers reveal differential entropy patterns, particularly over visual cortices. Here, observed brain-behavior linkage between entropy and reaction time for slow performers suggests that entropy assays over sensory cortices might have predictive value for fatigue onset or shifts from on- to off-task states.

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10 分钟警觉任务中的多尺度熵。

研究表明，多尺度熵（跨时间尺度的大脑信号行为）在较低的时间尺度上会随着任务时间的疲劳而可靠地增加。然而，多尺度熵尚未在短期警觉任务（即≤ 10 分钟）中得到研究。为了弥补这一空白，我们研究了 10 分钟精神运动警觉测试（PVT）中的多尺度熵。34 名参与者在完成 PVT 时提供了神经数据。我们将任务的前 2 分钟与第 7 和第 8 分钟进行了比较，以避免末端喷发效应。结果表明，与任务开始时相比，任务后期较低时间尺度的多尺度熵增加，这表明多尺度熵是短时间警觉时任务疲劳开始的有力标志。对 "快 "和 "慢 "执行者的单独分析显示了不同的熵模式，尤其是在视觉皮层上。在此，观察到的慢速表现者的熵和反应时间之间的大脑行为联系表明，对感觉皮层进行熵检测可能对疲劳开始或从任务状态到非任务状态的转变具有预测价值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Psychophysiology 医学-神经科学

CiteScore

5.40

自引率

10.00%

发文量

177

审稿时长

3-8 weeks

期刊介绍： The International Journal of Psychophysiology is the official journal of the International Organization of Psychophysiology, and provides a respected forum for the publication of high quality original contributions on all aspects of psychophysiology. The journal is interdisciplinary and aims to integrate the neurosciences and behavioral sciences. Empirical, theoretical, and review articles are encouraged in the following areas: • Cerebral psychophysiology: including functional brain mapping and neuroimaging with Event-Related Potentials (ERPs), Positron Emission Tomography (PET), Functional Magnetic Resonance Imaging (fMRI) and Electroencephalographic studies. • Autonomic functions: including bilateral electrodermal activity, pupillometry and blood volume changes. • Cardiovascular Psychophysiology:including studies of blood pressure, cardiac functioning and respiration. • Somatic psychophysiology: including muscle activity, eye movements and eye blinks.