Spatial and spectral changes in cortical surface potentials during pinching versus thumb and index finger flexion

IF 2.5 4区医学 Q3 NEUROSCIENCES Neuroscience Letters Pub Date : 2024-11-26 DOI:10.1016/j.neulet.2024.138062

Panagiotis Kerezoudis , Michael A Jensen , Harvey Huang , Jeffrey G. Ojemann , Bryan T. Klassen , Nuri F. Ince , Dora Hermes , Kai J Miller

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Abstract

Electrocorticographic (ECoG) signals provide high-fidelity representations of sensorimotor cortex activation during contralateral hand movements. Understanding the relationship between independent and coordinated finger movements along with their corresponding ECoG signals is crucial for precise brain mapping and neural prosthetic development. We analyzed subdural ECoG signals from three adult epilepsy patients with subdural electrode arrays implanted for seizure foci identification. Patients performed a cue-based task consisting of thumb flexion, index finger flexion or a pinching movement of both fingers together. Broadband power changes were estimated using principal component analysis of the power spectrum. All patients showed significant increases in broadband power during each movement compared to rest. We created topological maps for each movement type on brain renderings and quantified spatial overlap between movement types using a resampling metric. Pinching exhibited the highest spatial overlap with index flexion, followed by superimposed index and thumb flexion, with the least overlap observed for thumb flexion alone. This analysis provides practical insights into the complex overlap of finger representations in the motor cortex during various movement types and may help guide more nuanced approaches to brain-computer interfaces and neural prosthetics.

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拇指和食指屈伸时皮层表面电位的空间和频谱变化。

皮层电图（ECoG）信号能高保真地反映对侧手部运动时感觉运动皮层的激活情况。了解独立和协调的手指运动与其相应的心电图信号之间的关系对于精确绘制大脑图谱和开发神经假肢至关重要。我们分析了三名成年癫痫患者的硬膜下心电图信号，这些患者植入了硬膜下电极阵列以识别癫痫发作灶。患者执行了一项基于线索的任务，包括拇指屈曲、食指屈曲或双指并拢捏合运动。利用功率谱的主成分分析估算宽带功率变化。与休息时相比，所有患者在每次运动时的宽带功率都有明显增加。我们在大脑渲染图上创建了每种运动类型的拓扑图，并使用重采样指标量化了运动类型之间的空间重叠。掐指运动与食指屈伸的空间重叠度最高，其次是食指和拇指的叠加屈伸，仅拇指屈伸的重叠度最低。这项分析提供了对各种运动类型中运动皮层中手指表征复杂重叠的实用见解，并可能有助于指导脑机接口和神经假肢的更细致方法。

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来源期刊

Neuroscience Letters 医学-神经科学

CiteScore

5.20

自引率

0.00%

发文量

408

审稿时长

50 days

期刊介绍： Neuroscience Letters is devoted to the rapid publication of short, high-quality papers of interest to the broad community of neuroscientists. Only papers which will make a significant addition to the literature in the field will be published. Papers in all areas of neuroscience - molecular, cellular, developmental, systems, behavioral and cognitive, as well as computational - will be considered for publication. Submission of laboratory investigations that shed light on disease mechanisms is encouraged. Special Issues, edited by Guest Editors to cover new and rapidly-moving areas, will include invited mini-reviews. Occasional mini-reviews in especially timely areas will be considered for publication, without invitation, outside of Special Issues; these un-solicited mini-reviews can be submitted without invitation but must be of very high quality. Clinical studies will also be published if they provide new information about organization or actions of the nervous system, or provide new insights into the neurobiology of disease. NSL does not publish case reports.