Network-Based Asymmetry of the Human Auditory System

Cerebral Cortex (New York, NY) Pub Date : 2018-01-22 DOI:10.1101/251827

B. Mišić, Richard F. Betzel, A. Griffa, M. D. de Reus, Ye He, X. Zuo, M. P. van den Heuvel, P. Hagmann, O. Sporns, R. Zatorre

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引用次数: 46

Abstract

Converging evidence from activation, connectivity and stimulation studies suggests that auditory brain networks are lateralized. Here we show that these findings can be at least partly explained by the asymmetric network embedding of the primary auditory cortices. Using diffusion-weighted imaging in three independent datasets, we investigate the propensity for left and right auditory cortex to communicate with other brain areas by quantifying the centrality of the auditory network across a spectrum of communication mechanisms, from shortest path communication to diffusive spreading. Across all datasets, we find that the right auditory cortex is better integrated in the connectome, facilitating more efficient communication with other areas, with much of the asymmetry driven by differences in communication pathways to the opposite hemisphere. Critically, the primacy of the right auditory cortex emerges only when communication is conceptualized as a diffusive process, taking advantage of more than just the topologically shortest paths in the network. Altogether, these results highlight how the network configuration and embedding of a particular region may contribute to its functional lateralization.

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基于网络的人类听觉系统不对称性

来自激活、连接和刺激研究的越来越多的证据表明，大脑听觉网络是侧化的。在这里，我们表明这些发现至少可以部分解释为初级听觉皮层的不对称网络嵌入。利用三个独立数据集的扩散加权成像，我们通过量化听觉网络在一系列通信机制(从最短路径通信到弥漫性传播)中的中心性，研究了左右听觉皮层与其他大脑区域通信的倾向。在所有数据集中，我们发现右侧听觉皮层在连接组中整合得更好，促进了与其他区域更有效的交流，大部分不对称是由与相反半球的交流途径的差异造成的。关键的是，只有当沟通被定义为扩散过程时，右侧听觉皮层的首要地位才会出现，而不仅仅是利用网络中拓扑最短路径的优势。总之，这些结果强调了一个特定区域的网络结构和嵌入如何有助于其功能侧化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Cerebral Cortex (New York, NY)

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