通过降维来可视化大网络的过渡,以说明人类大脑的进化

F. Ganglberger, J. Kaczanowska, W. Haubensak, K. Bühler
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引用次数: 0

摘要

高通量成像技术的进步使得能够以前所未有的规模和幅度创建描绘时空生物和神经生理过程的网络。这些网络涉及数千个节点,由于复杂性和杂乱性,传统方法无法对其进行长期比较。当在多个时间步骤上研究网络时,可视化研究界的一个关键问题变得显而易见:如何在几个转换中可视化地跟踪连接的变化?因此,我们开发了一种易于使用的方法,将多个网络映射到一个共同的嵌入空间。可视化感兴趣的节点簇的分布(例如大脑区域)可以随着时间的推移进行追踪。我们通过将不同进化时间点的空间协同进化网络作为小倍数来研究人类大脑如何在哺乳动物谱系中遗传和功能进化来证明这种方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Visualising the Transition of Large Networks via Dimensionality Reduction to Illustrate the Evolution of the Human Brain
Advances in high-throughput imaging techniques enable the creation of networks depicting spatio-temporal biological and neurophysiological processes with unprecedented size and magnitude. These networks involve thousands of nodes, which can not be compared over time by traditional methods due to complexity and clutter. When investigating networks over multiple time steps, a crucial question for the visualisation research community becomes apparent: How to visually trace changes of the connectivity over several transitions? Therefore, we developed an easy-to-use method that maps multiple networks to a common embedding space. Visualising the distribution of node-clusters of interest (e.g. brain regions) enables their tracing over time. We demonstrate this approach by visualizing spatial co-evolution networks of different evolutionary timepoints as small multiples to investigate how the human brain genetically and functionally evolved over the mammalian lineage.
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