神经科学 25 年的关键性研究——成熟的成果、存在争议的问题、新颖的概念。

25 years of criticality in neuroscience - established results, open controversies, novel concepts.

机构信息

Max-Planck-Institute for Dynamics and Self-Organization, Göttingen, Germany.

Max-Planck-Institute for Dynamics and Self-Organization, Göttingen, Germany; Bernstein-Center for Computational Neuroscience, Göttingen, Germany.

出版信息

Curr Opin Neurobiol. 2019 Oct;58:105-111. doi: 10.1016/j.conb.2019.08.002. Epub 2019 Sep 21.

DOI:10.1016/j.conb.2019.08.002

PMID:31546053

Abstract

Twenty-five years ago, Dunkelmann and Radons (1994) showed that neural networks can self-organize to a critical state. In models, the critical state offers a number of computational advantages. Thus this hypothesis, and in particular the experimental work by Beggs and Plenz (2003), has triggered an avalanche of research, with thousands of studies referring to it. Nonetheless, experimental results are still contradictory. How is it possible, that a hypothesis has attracted active research for decades, but nonetheless remains controversial? We discuss the experimental and conceptual controversy, and then present a parsimonious solution that (i) unifies the contradictory experimental results, (ii) avoids disadvantages of a critical state, and (iii) enables rapid, adaptive tuning of network properties to task requirements.

摘要

25 年前，Dunkelmann 和 Radons（1994）表明神经网络可以自我组织到临界状态。在模型中，临界状态提供了许多计算优势。因此，这一假设，特别是 Beggs 和 Plenz（2003）的实验工作，引发了大量的研究，数千项研究都提到了这一假设。尽管如此，实验结果仍然存在矛盾。一个假设吸引了几十年的积极研究，但仍然存在争议，这是怎么可能的呢？我们讨论了实验和概念上的争议，然后提出了一个简洁的解决方案，（i）统一了矛盾的实验结果，（ii）避免了临界状态的缺点，（iii）使网络属性能够快速、自适应地适应任务要求。

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神经科学 25 年的关键性研究——成熟的成果、存在争议的问题、新颖的概念。

25 years of criticality in neuroscience - established results, open controversies, novel concepts.

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