临界点是大脑功能的统一设定点吗?

Keith B Hengen, Woodrow L Shew
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引用次数: 0

摘要

广义上讲,大脑面临着优化计算的选择性压力。这种优化是通过无数影响大脑计算状态的机制和过程实现的。这些机制和过程包括发育、可塑性、平衡等。尽管随着时间的推移和个体之间存在巨大差异,但这些不同的机制是否会趋同于同一个设定点?是否存在一个普遍的最佳计算状态,健康的大脑可以围绕它进行自我调整?临界点假说提出了这样一个统一的计算设定点。临界状态是一种特殊的大脑动力学状态,由内部产生的多尺度、边缘稳定的动力学所定义,它能最大限度地发挥信息处理的许多特性。二十年前,这一假说首次得到实验支持,尽管历史上存在争议,但证据仍在加速积累。在此,我们阐述了临界性作为一般计算终点的逻辑,并系统回顾了该假说的实验证据。我们对 2003 年至 2024 年间发表的 143 篇手稿数据集进行了荟萃分析。令我们惊讶的是,我们发现该领域长期存在的争议是一个简单方法选择的产物,与基本动力学无关。我们的研究结果表明,新一代研究可以利用临界性概念--作为大脑功能的统一原理--来加速我们对行为、认知和疾病的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Is criticality a unified set-point of brain function?
Brains face selective pressure to optimize computation, broadly defined. This optimization is achieved by myriad mechanisms and processes that influence the brain's computational state. These include development, plasticity, homeostasis, and more. Despite enormous variability over time and between individuals, do these diverse mechanisms converge on the same set-point? Is there a universal computational optimum around which the healthy brain tunes itself? The criticality hypothesis posits such a unified computational set-point. Criticality is a special dynamical brain state, defined by internally-generated multi-scale, marginally-stable dynamics which maximize many features of information processing. The first experimental support for this hypothesis emerged two decades ago, and evidence has accumulated at an accelerating pace, despite a contentious history. Here, we lay out the logic of criticality as a general computational end-point and systematically review experimental evidence for the hypothesis. We perform a meta-analysis of 143 datasets from manuscripts published between 2003 and 2024. To our surprise, we find that a long-standing controversy in the field is the product of a simple methodological choice that has no bearing on underlying dynamics. Our results suggest that a new generation of research can leverage the concept of criticality---as a unifying principle of brain function--to accelerate our understanding of behavior, cognition, and disease.
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