经颅皮层配对刺激可增加静息状态功能连接:原理验证研究。
Paired associative stimulation applied to the cortex can increase resting-state functional connectivity: A proof of principle study.
机构信息
School of Biological and Health Systems Engineering, Arizona State University, Tempe, AZ, USA.
Department of Physical Medicine and Rehabilitation, University of Colorado Anschutz Medical Campus, Aurora, CO, USA; Geriatric Research Education and Clinical Center, VA Eastern Colorado Health Care System, Aurora, CO, USA.
出版信息
Neurosci Lett. 2022 Jul 27;784:136753. doi: 10.1016/j.neulet.2022.136753. Epub 2022 Jun 23.
INTRODUCTION
There is emerging evidence that high Beta coherence (hBc) between prefrontal and motor corticies, measured with resting-state electroencephalography (rs-EEG), can be an accurate predictor of motor skill learning and stroke recovery. However, it remains unknown whether and how intracortical connectivity may be influenced using neuromodulation. Therefore, a cortico-cortico PAS (ccPAS) paradigm may be used to increase resting-state intracortical connectivity (rs-IC) within a targeted neural circuit.
PURPOSE
Our purpose is to demonstrate proof of principle that ccPAS can be used to increase rs-IC between a prefrontal and motor cortical region.
METHODS
Eleven non-disabled adults were recruited (mean age 26.4, sd 5.6, 5 female). Each participant underwent a double baseline measurement, followed by a real and control ccPAS condition, counter-balanced for order. Control and ccPAS conditions were performed over electrodes of the right prefrontal and motor cortex. Both ccPAS conditions were identical apart from the inter-stimulus interval (i.e ISI 5 ms: real ccPAS and 500 ms: control ccPAS). Whole brain rs-EEG of high Beta coherence (hBc) was acquired before and after each ccPAS condition and then analyzed for changes in rs-IC along the targeted circuit.
RESULTS
Compared to ccPAS500 and baseline, ccPAS5 induced a significant increase in rs-IC, measured as coherence between electrodes over right prefrontal and motor cortex, (p <.05).
CONCLUSION
These findings demonstrate proof of principle that ccPAS with an STDP derived ISI, can effectively increase hBc along a targeted circuit.
简介
越来越多的证据表明,通过静息态脑电图(rs-EEG)测量的前额叶和运动皮质之间的高β相干性(hBc)可以准确预测运动技能学习和中风恢复。然而,目前尚不清楚是否以及如何通过神经调节来影响皮质内连接。因此,可以使用皮质间短程传入刺激(ccPAS)范式来增加靶向神经回路中的静息状态皮质内连接(rs-IC)。
目的
我们的目的是证明 ccPAS 可用于增加前额叶和运动皮质区域之间的 rs-IC。
方法
招募了 11 名非残疾成年人(平均年龄 26.4,标准差 5.6,女性 5 名)。每位参与者进行了两次基线测量,随后进行了真实和对照 ccPAS 条件,按顺序平衡。对照和 ccPAS 条件均在右前额叶和运动皮质的电极上进行。除了刺激间间隔(即 5 ms:真实 ccPAS 和 500 ms:对照 ccPAS)外,两种 ccPAS 条件完全相同。在每个 ccPAS 条件前后采集大脑 rs-EEG 的高β相干性(hBc),并对靶向回路中的 rs-IC 变化进行分析。
结果
与 ccPAS500 和基线相比,ccPAS5 诱导 rs-IC 显著增加,表现为右前额叶和运动皮质之间电极的相干性增加(p<.05)。
结论
这些发现证明了原理,即使用具有 STDP 衍生的 ISI 的 ccPAS 可以有效地增加靶向电路中的 hBc。
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