物理医学与康复
前额叶皮质
功能近红外光谱
步态
医学
运动皮层
心理学
神经科学
冲程(发动机)
肌电图
认知
刺激
机械工程
工程类
作者
Pietro Caliandro,Franco Molteni,Chiara Simbolotti,Eleonora Guanziroli,Chiara Iacovelli,Giuseppe Reale,Silvia Giovannini,Luca Padua
标识
DOI:10.1016/j.clinph.2020.04.158
摘要
Gait impairment dramatically affects stroke patients’ functional independence. The Ekso™ is a wearable powered exoskeleton able to improve over-ground gait abilities, but the relationship between the cortical gait control mechanisms and lower limbs kinematics is still unclear. Our aims are: to assess whether the Ekso™ induces an attention-demanding process with prefrontal cortex activation during a gait task; to describe the relationship between the gait-induced muscle activation pattern and the prefrontal cortex activity. We enrolled 22 chronic stroke patients and 15 matched controls. We registered prefrontal cortex (PFC) activity with functional Near-Infrared Spectroscopy (fNIRS) and muscle activation with surface-electromyography (sEMG) during an over-ground gait task, performed with and without the Ekso™. We observed prefrontal cortex activation during normal gait and a higher activation during Ekso-assisted walking among stroke patients. Furthermore, we found that muscle hypo-activation and co-activation of non-paretic limb are associated to a high prefrontal metabolism. Among stroke patients, over-ground gait is an attention-demanding task. Prefrontal activity is modulated both by Ekso-assisted tasks and muscle activation patterns of non-paretic lower limb. Further studies are needed to elucidate if other Ekso™ settings induce different cortical and peripheral effects. This is the first study exploring the relationship between central and peripheral mechanisms during an Ekso-assisted gait task.
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