Adjustment of Synchronization Stability of Dynamic Brain-Networks Based on Feature Fusion.

Haifang Li,Pengfei Yang,Xiaoluan Xia,Rong Yao,Hongxia Deng,Guimei Yin

doi:10.3389/fnhum.2019.00098

Haifang Li, Pengfei Yang + Show 4 more

Open Access

https://doi.org/10.3389/fnhum.2019.00098

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Abstract

When the brain is active, the neural activities of different regions are integrated on various spatial and temporal scales; this is termed the synchronization phenomenon in neurobiological theory. This synchronicity is also the main underlying mechanism for information integration and processing in the brain. Clinical medicine has found that some of the neurological diseases that are difficult to cure have deficiencies or abnormalities in the whole or local integration processes of the brain. By studying the synchronization capabilities of the brain-network, we can intensively describe and characterize both the state of the interactions between brain regions and their differences between people with a mental illness and a set of controls by measuring the rapid changes in brain activity in patients with psychiatric disorders and the strength and integrity of their entire brain network. This is significant for the study of mental illness. Because static brain network connection methods are unable to assess the dynamic interactions within the brain, we introduced the concepts of dynamics and variability in a constructed EEG brain functional network based on dynamic connections, and used it to analyze the variability in the time characteristics of the EEG functional network. We used the spectral features of the brain network to extract its synchronization features and used the synchronization features to describe the process of change and the differences in the brain network's synchronization ability between a group of patients and healthy controls during a working memory task. We propose a method based on the fusion of traditional features and spectral features to achieve an adjustment of the patient's brain network synchronization ability, so that its synchronization ability becomes consistent with that of healthy controls, theoretically achieving the purpose of the treatment of the diseases. Studying the stability of brain network synchronization can provide new insights into the pathogenic mechanism and cure of mental diseases and has a wide range of potential applications.

Highlights

The brain is a complex system that exhibits various subsystems on different spatial and temporal scales
Synchronization Stability of Dynamic Brain-Networks dynamics theory to study EEG signals in 1985, research on EEG signals rapidly entered the era of nonlinear dynamics
Various theories and methods of nonlinear dynamics have opened up new possibilities for analyzing EEG data

Summary

INTRODUCTION

The brain is a complex system that exhibits various subsystems on different spatial and temporal scales. Previous studies have used synchrony to study neurodegenerative diseases, most of the current studies about the differences in brain function between patients with mental disorders and normal subjects investigated traditional features of brain network properties (node degree, meanclustering-coefficient, global-efficiency, small-world attributes, etc.) (Micheloyannis et al, 2006; Zhang et al, 2013a,b, 2015; Müller et al, 2018). Researching these traditional features can clearly aid in understanding the topological characteristics of the brain network, but these features do not fully reflect the structure of the brain network. Duration of the EEG trajectory in the encoding, maintenance, and retrieval phases were 100 s, 60 s, and 50 s, respectively

METHODS

Extraction of significant differences and nodes from local attributes

EXPERIMENTAL RESULTS AND ANALYSIS

LIMITATIONS

CONCLUSION