适应性重新布线:神经网络发展的一般原则

Frontiers in network physiology Pub Date : 2024-10-29 eCollection Date: 2024-01-01 DOI:10.3389/fnetp.2024.1410092
Jia Li, Roman Bauer, Ilias Rentzeperis, Cees van Leeuwen
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引用次数: 0

摘要

神经系统,尤其是人脑,具有高度复杂的网络拓扑结构。其某些特征的神经发育是通过动态优化规则来描述的。我们讨论了自适应重新布线原理,即根据同步或扩散测量的内部信号交流强度对网络进行动态重组,以及最近对其在有向网络中应用的推广。这些都将自适应重新布线的原理从高度简化的网络扩展到更符合神经学原理的网络。自适应重新布线捕捉到了复杂大脑拓扑结构的所有关键特征:它将最初的随机或规则网络转变为具有模块化小世界结构和富俱乐部核心的网络。这种效应是特殊的,因为它可以根据计算需要进行调整;它是稳健的,因为它不依赖于临界机制;它是灵活的,因为参数变化会产生一系列变异网络配置。极端变异网络在宏观层面上与精神分裂症、自闭症和阅读障碍等疾病有关,并表明阅读障碍与创造力之间存在关系。适应性重新布线与网络的增长相互配合,并与空间组织原理产生建设性的互动,从而形成拓扑上不同的模块和结构,如神经节和神经链。在中观层面,适应性重新布线促进了功能架构的发展,如收敛-发散单元,并揭示了视觉系统等的发散和收敛的早期发展。最后,我们讨论了自适应重新布线原理的未来前景。
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Adaptive rewiring: a general principle for neural network development.

The nervous system, especially the human brain, is characterized by its highly complex network topology. The neurodevelopment of some of its features has been described in terms of dynamic optimization rules. We discuss the principle of adaptive rewiring, i.e., the dynamic reorganization of a network according to the intensity of internal signal communication as measured by synchronization or diffusion, and its recent generalization for applications in directed networks. These have extended the principle of adaptive rewiring from highly oversimplified networks to more neurally plausible ones. Adaptive rewiring captures all the key features of the complex brain topology: it transforms initially random or regular networks into networks with a modular small-world structure and a rich-club core. This effect is specific in the sense that it can be tailored to computational needs, robust in the sense that it does not depend on a critical regime, and flexible in the sense that parametric variation generates a range of variant network configurations. Extreme variant networks can be associated at macroscopic level with disorders such as schizophrenia, autism, and dyslexia, and suggest a relationship between dyslexia and creativity. Adaptive rewiring cooperates with network growth and interacts constructively with spatial organization principles in the formation of topographically distinct modules and structures such as ganglia and chains. At the mesoscopic level, adaptive rewiring enables the development of functional architectures, such as convergent-divergent units, and sheds light on the early development of divergence and convergence in, for example, the visual system. Finally, we discuss future prospects for the principle of adaptive rewiring.

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