关键期:视觉皮层和脑干呼吸系统共有的神经化学和突触机制。
The critical period: neurochemical and synaptic mechanisms shared by the visual cortex and the brain stem respiratory system.
机构信息
Department of Cell Biology, Neurobiology and Anatomy, Medical College of Wisconsin, Milwaukee, WI 53226, USA.
出版信息
Proc Biol Sci. 2021 Sep 8;288(1958):20211025. doi: 10.1098/rspb.2021.1025.
Abstract
The landmark studies of Wiesel and Hubel in the 1960's initiated a surge of investigations into the critical period of visual cortical development, when abnormal visual experience can alter cortical structures and functions. Most studies focused on the visual cortex, with relatively little attention to subcortical structures. The goal of the present review is to elucidate neurochemical and synaptic mechanisms common to the critical periods of the visual cortex and the brain stem respiratory system in the rat. In both regions, the critical period is a time of (i) heightened inhibition; (ii) expression of brain-derived neurotrophic factor (BDNF); and (iii) , with heightened inhibition and suppressed excitation. The last two mechanisms are contrary to the conventional premise. Synaptic imbalance renders developing neurons more vulnerable to external stressors. However, the critical period is to enable each system to strengthen its circuitry, adapt to its environment, and transition from immaturity to maturity, when a state of relative synaptic balance is attained. Failure to achieve such a balance leads to neurological disorders.
摘要
20 世纪 60 年代,威塞尔和休贝尔的里程碑式研究引发了对视觉皮层发育关键期的大量研究,在此期间,异常的视觉体验可以改变皮层结构和功能。大多数研究都集中在视觉皮层,而对皮质下结构的关注相对较少。本综述的目的是阐明与视觉皮层和大鼠脑干呼吸系统的关键期共同的神经化学和突触机制。在这两个区域,关键期是(i)抑制作用增强;(ii)脑源性神经营养因子(BDNF)的表达;(iii)抑制作用增强,兴奋作用受到抑制。后两种机制与传统假设相悖。突触失衡使发育中的神经元更容易受到外部应激源的影响。然而,关键期是为了使每个系统能够加强其电路,适应其环境,并从不成熟过渡到成熟,当达到相对突触平衡的状态时。未能实现这种平衡会导致神经紊乱。
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