自适应再布线网络中的视网膜波协调了视觉系统中的聚合和发散。

IF 3.6 3区 医学 Q2 NEUROSCIENCES
Network Neuroscience Pub Date : 2024-10-01 eCollection Date: 2024-01-01 DOI:10.1162/netn_a_00370
Raúl Luna, Jia Li, Roman Bauer, Cees van Leeuwen
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引用次数: 0

摘要

塑造视觉系统的自发性视网膜波活动是一种复杂的神经发育现象。视网膜神经节细胞是整个视觉系统活动分化的枢纽。我们利用自适应重布线神经网络模型来研究这些分化的枢纽是如何出现的。自适应重新布线模型以一种原则性的方式展示了大脑如何实现其复杂的拓扑结构。具有丰富俱乐部效应的模块化小世界结构和收敛-发散单元回路会随着网络的演化而出现,并受到其自身自发活动的驱动。初始随机模型网络的任意节点被指定为视网膜神经节细胞。当网络通过适应性重新布线进化时,它们会间歇性地暴露在视网膜波形中。在这些节点中,有相当一部分发展成为复杂网络结构特征中的分化中心。这一比例取决于波发生率的参数。入射率越高,形成集线器的可能性越大,同时神经节细胞死亡的可能性也越大。此外,指定神经节细胞的直接邻近细胞会像羊膜细胞一样分化。在神经节细胞中观察到的分化导致下游汇聚增强,这表明视网膜波控制着外侧膝状核汇聚的形成。我们的结论是,视网膜波随机控制着复杂网络中聚合和发散活动的分布。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Retinal waves in adaptive rewiring networks orchestrate convergence and divergence in the visual system.

Spontaneous retinal wave activity shaping the visual system is a complex neurodevelopmental phenomenon. Retinal ganglion cells are the hubs through which activity diverges throughout the visual system. We consider how these divergent hubs emerge, using an adaptively rewiring neural network model. Adaptive rewiring models show in a principled way how brains could achieve their complex topologies. Modular small-world structures with rich-club effects and circuits of convergent-divergent units emerge as networks evolve, driven by their own spontaneous activity. Arbitrary nodes of an initially random model network were designated as retinal ganglion cells. They were intermittently exposed to the retinal waveform, as the network evolved through adaptive rewiring. A significant proportion of these nodes developed into divergent hubs within the characteristic complex network architecture. The proportion depends parametrically on the wave incidence rate. Higher rates increase the likelihood of hub formation, while increasing the potential of ganglion cell death. In addition, direct neighbors of designated ganglion cells differentiate like amacrine cells. The divergence observed in ganglion cells resulted in enhanced convergence downstream, suggesting that retinal waves control the formation of convergence in the lateral geniculate nuclei. We conclude that retinal waves stochastically control the distribution of converging and diverging activity in evolving complex networks.

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来源期刊
Network Neuroscience
Network Neuroscience NEUROSCIENCES-
CiteScore
6.40
自引率
6.40%
发文量
68
审稿时长
16 weeks
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