Simultaneous monitoring of the human brain, spinal cord, and cauda equina activity for movement control: An fNIRS approach

IF 4.7 2区医学 Q1 NEUROIMAGING

NeuroImage Pub Date : 2025-04-17 DOI:10.1016/j.neuroimage.2025.121216

Hojeong Kim

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引用次数: 0

Abstract

Brain‒spinal cord‒cauda equina interactions are essential for controlling lower body movement. However, current monitoring approaches for spinal and caudal activity are limited to use without body movement and to processing via batches of data. Here, we present a novel optical method based on functional near-infrared spectroscopy that enables simultaneous tracking of human brain-spinal cord-cauda equina hemodynamics during body movement. We first developed a support frame for positioning optical emitters and receivers along the spinal canal to maximize spatial resolution and identify the optimal distance between them. We tested the methodology at this optimal emitter-detector distance by assessing the spatiotemporal activation of the motor clusters associated with human ankle extension-flexion movement in the brain, spinal cord, and cauda equina. These brain and spinal clusters are shown to be functionally connected and comparable to those identified by invasive methods during surgical operations. These findings suggest that hemodynamic responses reflect synchronous neural activity in the human brain-spinal cord-cauda equina system for hindlimb movement control.

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同时监测人脑、脊髓和马尾的运动控制活动：近红外光谱方法

大脑-脊髓-马尾的相互作用对于控制下半身运动至关重要。然而，目前对脊髓和尾椎活动的监测方法仅限于在没有身体运动的情况下使用，并且只能通过批量数据进行处理。在此，我们介绍了一种基于功能性近红外光谱的新型光学方法，该方法可在人体运动时同步跟踪人脑-脊髓-马尾的血液动力学。我们首先开发了一个支撑架，用于沿椎管定位光学发射器和接收器，以最大限度地提高空间分辨率，并确定它们之间的最佳距离。我们通过评估大脑、脊髓和马尾中与人体踝关节伸屈运动相关的运动集群的时空激活情况，测试了最佳发射器-接收器距离下的方法。结果表明，这些大脑和脊髓运动集群在功能上是相互关联的，与外科手术中通过侵入性方法识别的运动集群具有可比性。这些研究结果表明，血液动力学反应反映了人脑-脊髓-马尾神经系统在后肢运动控制方面的同步神经活动。

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

NeuroImage 医学-核医学

CiteScore

11.30

自引率

10.50%

发文量

809

审稿时长

63 days

期刊介绍： NeuroImage, a Journal of Brain Function provides a vehicle for communicating important advances in acquiring, analyzing, and modelling neuroimaging data and in applying these techniques to the study of structure-function and brain-behavior relationships. Though the emphasis is on the macroscopic level of human brain organization, meso-and microscopic neuroimaging across all species will be considered if informative for understanding the aforementioned relationships.