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I型神经元型一氧化氮合酶神经元协调皮层神经活动和血管运动。

Type-I nNOS neurons orchestrate cortical neural activity and vasomotion.

作者信息

Turner Kevin, Brockway Dakota, Hossain Md Shakhawat, Griffith Keith, Greenawalt Denver, Zhang Qingguang, Gheres Kyle, Crowley Nicole, Drew Patrick J

机构信息

Department of Engineering Science and Mechanics, The Pennsylvania State University, University Park, United States.

Center for Neural Engineering, The Pennsylvania State University, University Park, United States.

出版信息

Elife. 2025 Nov 11;14:RP105649. doi: 10.7554/eLife.105649.

DOI:10.7554/eLife.105649
PMID:41217439
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12604857/
Abstract

It is unknown how the brain orchestrates coordination of global neural and vascular dynamics. We sought to uncover the role of a sparse but unusual population of genetically distinct interneurons known as type-I nNOS neurons, using a novel pharmacological strategy to unilaterally ablate these neurons from the somatosensory cortex of mice. Region-specific ablation produced changes in both neural activity and vascular dynamics, decreased power in the delta-band of the local field potential, reduced sustained vascular responses to prolonged sensory stimulation, and abolished the post-stimulus undershoot in cerebral blood volume. Coherence between the left and right somatosensory cortex gamma-band power envelope and blood volume at ultra-low frequencies was decreased, suggesting type-1 nNOS neurons integrate long-range coordination of brain signals. Lastly, we observed decreases in the amplitude of resting-state blood volume oscillations and decreased vasomotion following the ablation of type-I nNOS neurons. This demonstrates that a small population of nNOS-positive neurons is indispensable for regulating both neural and vascular dynamics in the whole brain, raising the possibility that loss of these neurons could contribute to the development of neurodegenerative diseases and sleep disturbances.

摘要

目前尚不清楚大脑是如何协调整体神经和血管动力学的。我们试图利用一种新颖的药理学策略,从小鼠体感皮层单侧消融一类稀疏但独特的、基因上不同的中间神经元——I型nNOS神经元,来揭示其作用。区域特异性消融导致神经活动和血管动力学均发生变化,局部场电位的δ波段功率降低,对长时间感觉刺激的持续性血管反应减弱,并且消除了脑血容量的刺激后下冲。左右体感皮层γ波段功率包络与超低频血容量之间的相干性降低,表明I型nNOS神经元整合了脑信号的长程协调。最后,我们观察到I型nNOS神经元消融后静息态血容量振荡的幅度降低以及血管运动减弱。这表明一小群nNOS阳性神经元对于调节全脑的神经和血管动力学不可或缺,提示这些神经元的缺失可能导致神经退行性疾病和睡眠障碍的发生。

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