Beta-band power modulation in the human amygdala during a delayed reach task

IF 1.8 4区医学 Q3 CLINICAL NEUROLOGY Journal of Clinical Neuroscience Pub Date : 2025-05-01 Epub Date: 2025-02-27 DOI:10.1016/j.jocn.2025.111151

Shivani Sundaram , Xiecheng Shao , Ryan S. Chung , Roberto Martin del Campo Vera , Jonathon Cavaleri , Miguel Parra , Selena Zhang , Adith Swarup , Alexandra Kammen , Christi Heck , Charles Y. Liu , Spencer S. Kellis , Brian Lee

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Abstract

Introduction

The amygdala is mostly known for its roles in emotional processing and social behavior. In recent years, it has been implicated in voluntary motor control due to its structural and functional connectivity with the motor cortex. By investigating whether the amygdala modulates during movement preparation, we can further examine its contributions to motor processing.

Objective

We utilized a delayed reach task to measure beta-band (13–30 Hz) modulation in the amygdala during movement preparation. We hypothesized that we would see decreases in beta-band power during the Delay and Response phases of this task.

Methods

Eleven subjects diagnosed with drug-resistant epilepsy (DRE), who were implanted with stereoelectroencephalographic (SEEG) electrodes, were recruited to this study. The beta-band power was recorded through a delayed reach task. We calculated the beta-band Power Spectral Density (PSD) using multi-taper spectral analysis and compared the trial-averaged PSD using a cluster-based permutation test to determine the significance of beta-band power differences between task phases.

Results

100 % of participants and 44.8 % of gray matter contacts in the amygdala (n = 58) exhibited significantly decreased beta-band power during the Delay phase. During the Response phase, 90.9 % of participants and 58.6 % of gray matter contacts (n = 58) showed significantly decreased beta-band power. We also found a difference in the proportion of amygdala contacts showing beta-band modulation between those implanted in gray vs. white matter (p = 0.0035) but found no difference between contralateral vs. ipsilateral contacts (p = 0.17) and male vs. female participants (p = 0.34).

Conclusion

This study is the first to demonstrate beta-band power decreases in the amygdala during the Delay and Response phases of a delayed reach task. These findings demonstrate that the amygdala undergoes neural modulation prior to movement initiation and during movement execution.

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延迟到达任务中人类杏仁核的β波段功率调制

杏仁核以其在情绪处理和社会行为中的作用而闻名。近年来，由于其与运动皮层的结构和功能连接，它被认为与随意运动控制有关。通过研究杏仁核是否在运动准备过程中调节，我们可以进一步研究它对运动加工的贡献。目的利用延迟到达任务测量运动准备过程中杏仁核的β -波段（13-30 Hz）调制。我们假设，在这个任务的延迟和响应阶段，我们会看到β波段功率的下降。方法招募被诊断为耐药癫痫（DRE）的受试者，并植入立体脑电图（SEEG）电极。通过延迟到达任务记录β波段功率。我们使用多锥度谱分析计算了beta波段功率谱密度（PSD），并使用基于聚类的排列检验比较了试验平均PSD，以确定任务阶段之间beta波段功率差异的显著性。结果100%的参与者和44.8%的杏仁核灰质接触（n = 58）在延迟阶段表现出显著的β波段功率下降。在反应阶段，90.9%的参与者和58.6%的灰质接触（n = 58）表现出显著的β波段功率下降。我们还发现，在灰质与白质植入者之间，杏仁核接触显示β波段调制的比例存在差异（p = 0.0035），但在对侧与同侧接触者（p = 0.17）和男性与女性参与者（p = 0.34）之间没有发现差异。结论本研究首次证实了在延迟到达任务的延迟和反应阶段，杏仁核的β波段功率降低。这些发现表明，杏仁核在运动开始前和运动执行过程中经历了神经调节。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Clinical Neuroscience 医学-临床神经学

CiteScore

4.50

自引率

0.00%

发文量

402

审稿时长

40 days

期刊介绍： This International journal, Journal of Clinical Neuroscience, publishes articles on clinical neurosurgery and neurology and the related neurosciences such as neuro-pathology, neuro-radiology, neuro-ophthalmology and neuro-physiology. The journal has a broad International perspective, and emphasises the advances occurring in Asia, the Pacific Rim region, Europe and North America. The Journal acts as a focus for publication of major clinical and laboratory research, as well as publishing solicited manuscripts on specific subjects from experts, case reports and other information of interest to clinicians working in the clinical neurosciences.