多变量多尺度熵(mMSE)作为理解静息状态EEG信号动力学的工具:空间分布和性别/性别相关差异。

IF 4.7 2区 心理学 Q1 BEHAVIORAL SCIENCES
Monika Lewandowska, Krzysztof Tołpa, Jacek Rogala, Tomasz Piotrowski, Joanna Dreszer
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引用次数: 0

摘要

背景:本研究旨在确定静息状态脑电图(rsEEG)的复杂性如何随时间和空间(通道)变化。使用多变量多尺度熵(mMSE)对95名健康成年人的rsEEG的复杂性及其性别/性别差异进行了检查。根据概率图(Giacometti等人在《神经科学方法杂志》229:84-962014),已经确定了对应于功能网络的通道集。对于每个通道集,分别提取代表总复杂度的曲线下面积(AUC)、脑电信号在精细尺度(1:4时间尺度)下的最大复杂度变化的MaxSlope和粗粒度尺度(9:12时间尺度)上平均熵水平的AvgEnt。为了检查细粒度和粗粒度尺度下熵水平之间的动态变化,还计算了#9和#4时间尺度之间的mMSE差异(DiffEnt)。结果:我们发现与躯体运动(SMN)、背外侧网络(DAN)和默认模式(DMN)相对应的通道集的AUC最高,而视觉网络(VN)、边缘网络(LN)和额顶网络(FPN)的AUC最低。最大斜率最大的是SMN、DMN、腹侧注意网络(VAN)、LN和FPN,最小的是VN。SMN和DAN的特征是最高,LN、FPN和VN的特征是最低的AvgEnt。最稳定的熵是DAN和VN,而LN在粗尺度上表现出最大的熵降。与男性相比,女性在所有频道中的MaxSlope和DiffEnt都较高,但AvgEnt较低。结论:本研究的新结果是:(1)在与主要静息状态网络相对应的通道集中,识别了在精细和粗略时间尺度上捕获熵的mMSE特征;(2) 这些特征中的性别差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Multivariate multiscale entropy (mMSE) as a tool for understanding the resting-state EEG signal dynamics: the spatial distribution and sex/gender-related differences.

Multivariate multiscale entropy (mMSE) as a tool for understanding the resting-state EEG signal dynamics: the spatial distribution and sex/gender-related differences.

Multivariate multiscale entropy (mMSE) as a tool for understanding the resting-state EEG signal dynamics: the spatial distribution and sex/gender-related differences.

Multivariate multiscale entropy (mMSE) as a tool for understanding the resting-state EEG signal dynamics: the spatial distribution and sex/gender-related differences.

Background: The study aimed to determine how the resting-state EEG (rsEEG) complexity changes both over time and space (channels). The complexity of rsEEG and its sex/gender differences were examined using the multivariate Multiscale Entropy (mMSE) in 95 healthy adults. Following the probability maps (Giacometti et al. in J Neurosci Methods 229:84-96, 2014), channel sets have been identified that correspond to the functional networks. For each channel set the area under curve (AUC), which represents the total complexity, MaxSlope-the maximum complexity change of the EEG signal at thefine scales (1:4 timescales), and AvgEnt-to the average entropy level at coarse-grained scales (9:12 timescales), respectively, were extracted. To check dynamic changes between the entropy level at the fine and coarse-grained scales, the difference in mMSE between the #9 and #4 timescale (DiffEnt) was also calculated.

Results: We found the highest AUC for the channel sets corresponding to the somatomotor (SMN), dorsolateral network (DAN) and default mode (DMN) whereas the visual network (VN), limbic (LN), and frontoparietal (FPN) network showed the lowest AUC. The largest MaxSlope were in the SMN, DMN, ventral attention network (VAN), LN and FPN, and the smallest in the VN. The SMN and DAN were characterized by the highest and the LN, FPN, and VN by the lowest AvgEnt. The most stable entropy were for the DAN and VN while the LN showed the greatest drop of entropy at the coarse scales. Women, compared to men, showed higher MaxSlope and DiffEnt but lower AvgEnt in all channel sets.

Conclusions: Novel results of the present study are: (1) an identification of the mMSE features that capture entropy at the fine and coarse timescales in the channel sets corresponding to the main resting-state networks; (2) the sex/gender differences in these features.

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来源期刊
Behavioral and Brain Functions
Behavioral and Brain Functions 医学-行为科学
CiteScore
5.90
自引率
0.00%
发文量
11
审稿时长
6-12 weeks
期刊介绍: A well-established journal in the field of behavioral and cognitive neuroscience, Behavioral and Brain Functions welcomes manuscripts which provide insight into the neurobiological mechanisms underlying behavior and brain function, or dysfunction. The journal gives priority to manuscripts that combine both neurobiology and behavior in a non-clinical manner.
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