Spatial decomposition of ultrafast ultrasound images to identify motor unit activity – A comparative study with intramuscular and surface EMG

IF 2 4区 医学 Q3 NEUROSCIENCES
Robin Rohlén , Emma Lubel , Bruno Grandi Sgambato , Christian Antfolk , Dario Farina
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引用次数: 1

Abstract

The smallest voluntarily controlled structure of the human body is the motor unit (MU), comprised of a motoneuron and its innervated fibres. MUs have been investigated in neurophysiology research and clinical applications, primarily using electromyographic (EMG) techniques. Nonetheless, EMG (both surface and intramuscular) has a limited detection volume. A recent alternative approach to detect MUs is ultrafast ultrasound (UUS) imaging. The possibility of identifying MU activity from UUS has been shown by blind source separation (BSS) of UUS images, using optimal separation spatial filters. However, this approach has yet to be fully compared with EMG techniques for a large population of unique MU spike trains. Here we identify individual MU activity in UUS images using the BSS method for 401 MU spike trains from eleven participants based on concurrent recordings of either surface or intramuscular EMG from forces up to 30% of the maximum voluntary contraction (MVC) force. We assessed the BSS method’s ability to identify MU spike trains from direct comparison with the EMG-derived spike trains as well as twitch areas and temporal profiles from comparison with the spike-triggered-averaged UUS images when using the EMG-derived spikes as triggers. We found a moderate rate of correctly identified spikes (53.0 ± 16.0%) with respect to the EMG-identified firings. However, the MU twitch areas and temporal profiles could still be identified accurately, including at 30% MVC force. These results suggest that the current BSS methods for UUS can accurately identify the location and average twitch of a large pool of MUs in UUS images, providing potential avenues for studying neuromechanics from a large cross-section of the muscle. On the other hand, more advanced methods are needed to address the convolutive and partly non-linear summation of velocities for recovering the full spike trains.

识别运动单位活动的超快超声图像的空间分解——与肌内和表面肌电图的比较研究。
人体最小的自主控制结构是运动单元(MU),由运动神经元及其神经支配纤维组成。MU已在神经生理学研究和临床应用中进行了研究,主要使用肌电图(EMG)技术。尽管如此,EMG(表面和肌肉内)的检测量有限。最近检测MUs的一种替代方法是超快超声(UUS)成像。通过使用最优分离空间滤波器对UUS图像进行盲源分离(BSS),表明了从UUS中识别MU活动的可能性。然而,对于大量独特的MU尖峰序列,这种方法尚未与EMG技术进行完全比较。在这里,我们使用BSS方法识别UUS图像中的个体MU活动,该方法针对来自11名参与者的401个MU刺突序列,基于来自最大自主收缩(MVC)力的30%的力的表面或肌内EMG的同时记录。当使用EMG衍生的尖峰作为触发时,我们评估了BSS方法通过与EMG衍生尖峰序列的直接比较来识别MU尖峰序列的能力,以及通过与尖峰触发的平均UUS图像的比较来识别抽搐区域和时间轮廓的能力。我们发现,相对于EMG识别的发射,正确识别尖峰的比率适中(53.0±16.0%)。然而,MU抽搐区域和时间剖面仍然可以准确识别,包括在30%MVC力下。这些结果表明,目前用于UUS的BSS方法可以准确识别UUS图像中大量MU的位置和平均抽搐,为从大截面肌肉研究神经机制提供了潜在的途径。另一方面,需要更先进的方法来解决速度的卷积和部分非线性求和,以恢复完整的尖峰序列。
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来源期刊
CiteScore
4.70
自引率
8.00%
发文量
70
审稿时长
74 days
期刊介绍: Journal of Electromyography & Kinesiology is the primary source for outstanding original articles on the study of human movement from muscle contraction via its motor units and sensory system to integrated motion through mechanical and electrical detection techniques. As the official publication of the International Society of Electrophysiology and Kinesiology, the journal is dedicated to publishing the best work in all areas of electromyography and kinesiology, including: control of movement, muscle fatigue, muscle and nerve properties, joint biomechanics and electrical stimulation. Applications in rehabilitation, sports & exercise, motion analysis, ergonomics, alternative & complimentary medicine, measures of human performance and technical articles on electromyographic signal processing are welcome.
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