大脑皮层中突触兴奋和抑制的宏观梯度。

Macroscopic gradients of synaptic excitation and inhibition in the neocortex.

机构信息

Center for Neural Science, New York University, New York, NY, USA.

出版信息

Nat Rev Neurosci. 2020 Mar;21(3):169-178. doi: 10.1038/s41583-020-0262-x. Epub 2020 Feb 6.

DOI:10.1038/s41583-020-0262-x

PMID:32029928

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7334830/

Abstract

With advances in connectomics, transcriptome and neurophysiological technologies, the neuroscience of brain-wide neural circuits is poised to take off. A major challenge is to understand how a vast diversity of functions is subserved by parcellated areas of mammalian neocortex composed of repetitions of a canonical local circuit. Areas of the cerebral cortex differ from each other not only in their input-output patterns but also in their biological properties. Recent experimental and theoretical work has revealed that such variations are not random heterogeneities; rather, synaptic excitation and inhibition display systematic macroscopic gradients across the entire cortex, and they are abnormal in mental illness. Quantitative differences along these gradients can lead to qualitatively novel behaviours in non-linear neural dynamical systems, by virtue of a phenomenon mathematically described as bifurcation. The combination of macroscopic gradients and bifurcations, in tandem with biological evolution, development and plasticity, provides a generative mechanism for functional diversity among cortical areas, as a general principle of large-scale cortical organization.

摘要

随着连接组学、转录组学和神经生理学技术的进步，脑全脑神经回路的神经科学正蓄势待发。一个主要的挑战是要理解由哺乳动物新皮层的重复组成的分区区域如何为多样化的功能提供支持。大脑皮层的区域不仅在其输入-输出模式上彼此不同，而且在其生物学特性上也不同。最近的实验和理论工作表明，这种变化不是随机的异质性；相反，突触兴奋和抑制在整个皮层中呈现出系统的宏观梯度，并且在精神疾病中是异常的。沿着这些梯度的定量差异可以通过一种在数学上被描述为分岔的现象，导致非线性神经动力学系统中具有定性新颖的行为。宏观梯度和分岔的结合，以及生物进化、发育和可塑性，为皮层区域之间的功能多样性提供了一种生成机制，这是大规模皮层组织的一个普遍原则。

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