Exploring nonlinear dynamics in brain functionality through phase portraits and fuzzy recurrence plots.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-01 DOI:10.1063/5.0203926
Qiang Li, Vince D Calhoun, Tuan D Pham, Armin Iraji
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Abstract

Much of the complexity and diversity found in nature is driven by nonlinear phenomena, and this holds true for the brain. Nonlinear dynamics theory has been successfully utilized in explaining brain functions from a biophysics standpoint, and the field of statistical physics continues to make substantial progress in understanding brain connectivity and function. This study delves into complex brain functional connectivity using biophysical nonlinear dynamics approaches. We aim to uncover hidden information in high-dimensional and nonlinear neural signals, with the hope of providing a useful tool for analyzing information transitions in functionally complex networks. By utilizing phase portraits and fuzzy recurrence plots, we investigated the latent information in the functional connectivity of complex brain networks. Our numerical experiments, which include synthetic linear dynamics neural time series and a biophysically realistic neural mass model, showed that phase portraits and fuzzy recurrence plots are highly sensitive to changes in neural dynamics and can also be used to predict functional connectivity based on structural connectivity. Furthermore, the results showed that phase trajectories of neuronal activity encode low-dimensional dynamics, and the geometric properties of the limit-cycle attractor formed by the phase portraits can be used to explain the neurodynamics. Additionally, our results showed that the phase portrait and fuzzy recurrence plots can be used as functional connectivity descriptors, and both metrics were able to capture and explain nonlinear dynamics behavior during specific cognitive tasks. In conclusion, our findings suggest that phase portraits and fuzzy recurrence plots could be highly effective as functional connectivity descriptors, providing valuable insights into nonlinear dynamics in the brain.

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通过相位肖像和模糊递推图探索大脑功能的非线性动态。
自然界的复杂性和多样性大多由非线性现象驱动,大脑也是如此。非线性动力学理论已被成功地用于从生物物理学的角度解释大脑功能,统计物理学领域在理解大脑连接和功能方面不断取得实质性进展。本研究采用生物物理非线性动力学方法深入研究复杂的大脑功能连接。我们旨在揭示高维非线性神经信号中的隐藏信息,希望为分析功能复杂网络中的信息转换提供有用的工具。通过利用相位肖像和模糊递推图,我们研究了复杂大脑网络功能连接中的潜在信息。我们的数值实验包括合成线性动力学神经时间序列和生物物理现实神经质量模型,结果表明相位描绘和模糊递推图对神经动力学变化高度敏感,也可用于根据结构连通性预测功能连通性。此外,研究结果表明,神经元活动的相位轨迹编码了低维动力学,而相位肖像形成的极限循环吸引子的几何特性可用来解释神经动力学。此外,我们的研究结果表明,相位肖像和模糊递推图可用作功能连接描述符,这两种指标都能捕捉和解释特定认知任务中的非线性动力学行为。总之,我们的研究结果表明,相位肖像和模糊递推图作为功能连通性描述符非常有效,可为大脑非线性动力学提供有价值的见解。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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