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中文核心期刊

脑复杂网络的刚度与阻尼特性分析

STIFFNESS AND DAMPING FEATURES OF BRAIN COMPLEX NETWORKS

  • 摘要: 脑神经系统与机械振动系统表现出相似的振荡行为. 机械系统的振荡与刚度和阻尼密切相关, 但脑神经系统是否具有刚度和阻尼特性尚不清楚. 基于经典的FitzHugh-Nagumo (FHN)神经元模型, 建立了以通道打开概率为状态变量, 并具有非线性变刚度和变阻尼的神经元振动力学模型. 首先, 通过分析单FHN神经元的动力学行为, 给出了负阻尼和弱刚度支持FHN神经元动作电位产生, 以及强阻尼诱发神经元不应期的动力学机制. 其次, 建立了大尺度脑复杂网络振动力学模型, 分析了系统相对应的主刚度和主阻尼, 发现了静息态大脑左半球的刚度和阻尼低于右半球, 高级功能系统的刚度和阻尼低于低级功能系统. 再次, 通过变化全局耦合强度参数, 给出了中等程度的刚度和阻尼支持静息态大脑功能性平衡的证据. 最后, 基于3种认知任务和统计学因子分析, 发现了执行控制功能与静息态大脑较低的刚度和较高的阻尼有关. 文章通过单个FHN神经元和脑复杂网络分析, 揭示了脑神经系统的刚度和阻尼特性.

     

    Abstract: Brain neural systems and mechanical vibration systems share similar oscillatory behavior. In mechanical systems, oscillation depends on stiffness and damping, where stiffness reflects the amplitude of the system's response to external stimulation, and damping characterizes the decay of the system's state. Although responses and decay also occur in the neural system, it is unclear whether the brain exhibits similar features of stiffness and damping. Using the classical FitzHugh-Nagumo (FHN) neuron model, we proposed a mechanical model for the neuron that includes the state variable of the ion channels' opening probability, as well as nonlinear stiffness and damping. First, we analyzed the dynamic behavior of a single FHN neuron and revealed that negative damping and weak stiffness jointly support the generation of neuron action potentials, while strong damping induces the refractory period. Second, we constructed a mechanical model for the large-scale brain complex network wherein all model parameters were automatically identified via the Bayesian optimization. By analyzing the corresponding principal stiffness and damping of the system, we found that the left hemisphere of the resting brain has lower stiffness and damping compared to the right hemisphere, and that higher-order functional systems exhibit lower stiffness and damping than lower-order functional systems. Then, by varying the global coupling strength, we revealed that moderate stiffness and damping support the functional balance of the resting-state brain. Finally, through the combination of three cognitive tasks and statistical factor analysis, we found that executive control function is associated with lower stiffness and higher damping. These findings illuminate the mechanical properties of the brain neural system through the analysis of a single neuron and brain complex network.

     

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