Klassen Bryan T, Baker Matthew R, Jensen Michael A, Ojeda Valencia Gabriela, Miller Kai J
Department of Neurology, Mayo Clinic, Rochester, Minnesota, United States.
Department of Neurosurgery, Mayo Clinic, Rochester, Minnesota, United States.
J Neurophysiol. 2025 Jan 1;133(1):101-108. doi: 10.1152/jn.00419.2024. Epub 2024 Nov 26.
The motor thalamus plays a crucial role in integrating and modulating sensorimotor information. Although voltage power spectral changes in the motor cortex with movement are well-characterized, corresponding activity in the motor thalamus, particularly broadband power change, remains unclear. The present study aims to characterize spectral changes in the motor thalamus during hand movements of 15 subjects undergoing awake deep brain stimulation surgery targeting the ventral intermediate (Vim) nucleus of the thalamus for disabling tremor. We analyzed power changes in subject-specific low-frequency oscillations (<30 Hz) and broadband power (captured in 65-115 Hz band) of serial field potential recordings. Consistent with previous studies, we found widespread decreases in low-frequency oscillations with movement. Importantly, in most subjects, we observed that sites with significant increases in broadband power were more spatially discrete, primarily involving the inferior recording sites within the ventral thalamus. One subject also performed an imagined movement task during which low-frequency oscillatory power was suppressed. These electrophysiological changes may be leveraged as biomarkers for thalamic functional mapping, DBS targeting, and closed-loop applications. We studied movement-associated spectral changes in human motor thalamus and observed focal increases in broadband power with movement. This biomarker may be used as a tool for intraoperative functional mapping, DBS targeting, and closed-loop device control.
运动丘脑在整合和调节感觉运动信息方面起着关键作用。虽然运动皮层随运动的电压功率谱变化已得到充分表征,但运动丘脑中的相应活动,尤其是宽带功率变化,仍不清楚。本研究旨在表征15名接受清醒状态下深部脑刺激手术的受试者手部运动期间运动丘脑的频谱变化,该手术以丘脑腹中间(Vim)核为靶点来治疗震颤。我们分析了连续场电位记录中受试者特异性低频振荡(<30Hz)和宽带功率(在65 - 115Hz频段捕获)的功率变化。与先前研究一致,我们发现运动时低频振荡普遍减少。重要的是,在大多数受试者中,我们观察到宽带功率显著增加的部位在空间上更离散,主要涉及丘脑腹侧的下部记录部位。一名受试者还执行了想象运动任务,在此期间低频振荡功率受到抑制。这些电生理变化可作为丘脑功能映射、深部脑刺激靶点定位和闭环应用的生物标志物。我们研究了人类运动丘脑中与运动相关的频谱变化,并观察到运动时宽带功率的局部增加。这种生物标志物可作为术中功能映射、深部脑刺激靶点定位和闭环设备控制的工具。
