脑电微态转换的噪声网络吸引子模型。

IF 2.3 4区 医学 Q1 Neuroscience Journal of Mathematical Neuroscience Pub Date : 2021-01-04 DOI:10.1186/s13408-020-00100-0
Jennifer Creaser, Peter Ashwin, Claire Postlethwaite, Juliane Britz
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引用次数: 7

摘要

大脑在本质上被组织成大规模的网络,在多个时间尺度上不断重组,即使大脑处于休息状态。这些动态的时间对感觉、知觉、认知和最终的意识至关重要,但控制网络之间不断重组和切换的潜在动态尚未得到很好的理解。脑电图(EEG)微状态是稳定的头皮地形的短暂时期,已被确定为功能磁共振成像定义的静息状态网络的电生理相关。时空微态序列保持高时间分辨率,并具有无标度的长程时间相关性。以前对EEG微状态序列建模的尝试未能捕捉到这一关键特性,因此无法完全捕捉到动态;本文响应了对更复杂的建模方法的需求。我们提出了一个动态模型,该模型显示了代表微观状态的节点之间的噪声网络吸引子。利用四个节点之间的可激网络,我们可以再现微观状态之间的跃迁概率,但不能再现重尾停留时间分布。我们对该模型进行了两个扩展:首先,在每个状态处增加一个隐藏节点;第二层是控制原始网络中交换频率的附加层。在网络中引入任意一种扩展都可以灵活地捕获这些重尾。我们将模型生成的序列与从健康受试者在休息时收集的脑电图数据的微状态序列进行比较。对于第一个扩展,我们证明了隐藏节点“捕获”了允许控制每个节点停留时间的轨迹。对于第二次扩展,我们证明了控制层中的两个节点足以模拟长停留时间。最后,我们表明,除了捕获序列的停留时间分布和转移概率外,这两个模型还捕获了序列的其他属性,包括与Hurst指数测量的数据相一致的长、短停留时间和长范围时间相关性。
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Noisy network attractor models for transitions between EEG microstates.

The brain is intrinsically organized into large-scale networks that constantly re-organize on multiple timescales, even when the brain is at rest. The timing of these dynamics is crucial for sensation, perception, cognition, and ultimately consciousness, but the underlying dynamics governing the constant reorganization and switching between networks are not yet well understood. Electroencephalogram (EEG) microstates are brief periods of stable scalp topography that have been identified as the electrophysiological correlate of functional magnetic resonance imaging defined resting-state networks. Spatiotemporal microstate sequences maintain high temporal resolution and have been shown to be scale-free with long-range temporal correlations. Previous attempts to model EEG microstate sequences have failed to capture this crucial property and so cannot fully capture the dynamics; this paper answers the call for more sophisticated modeling approaches. We present a dynamical model that exhibits a noisy network attractor between nodes that represent the microstates. Using an excitable network between four nodes, we can reproduce the transition probabilities between microstates but not the heavy tailed residence time distributions. We present two extensions to this model: first, an additional hidden node at each state; second, an additional layer that controls the switching frequency in the original network. Introducing either extension to the network gives the flexibility to capture these heavy tails. We compare the model generated sequences to microstate sequences from EEG data collected from healthy subjects at rest. For the first extension, we show that the hidden nodes 'trap' the trajectories allowing the control of residence times at each node. For the second extension, we show that two nodes in the controlling layer are sufficient to model the long residence times. Finally, we show that in addition to capturing the residence time distributions and transition probabilities of the sequences, these two models capture additional properties of the sequences including having interspersed long and short residence times and long range temporal correlations in line with the data as measured by the Hurst exponent.

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来源期刊
Journal of Mathematical Neuroscience
Journal of Mathematical Neuroscience Neuroscience-Neuroscience (miscellaneous)
自引率
0.00%
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审稿时长
13 weeks
期刊介绍: The Journal of Mathematical Neuroscience (JMN) publishes research articles on the mathematical modeling and analysis of all areas of neuroscience, i.e., the study of the nervous system and its dysfunctions. The focus is on using mathematics as the primary tool for elucidating the fundamental mechanisms responsible for experimentally observed behaviours in neuroscience at all relevant scales, from the molecular world to that of cognition. The aim is to publish work that uses advanced mathematical techniques to illuminate these questions. It publishes full length original papers, rapid communications and review articles. Papers that combine theoretical results supported by convincing numerical experiments are especially encouraged. Papers that introduce and help develop those new pieces of mathematical theory which are likely to be relevant to future studies of the nervous system in general and the human brain in particular are also welcome.
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