外骨骼康复机器人训练对脑卒中患者神经可塑性及下肢运动功能的影响

Effects of exoskeleton rehabilitation robot training on neuroplasticity and lower limb motor function in patients with stroke.

作者信息

Fan Tao, Zheng Peng, Zhang Xue, Gong Ze, Shi Yu, Wei Mingyang, Zhou Jing, He Longlong, Li Shilin, Zeng Qing, Lu Pengcheng, Zhao Yijin, Zou Jihua, Chen Rong, Peng Zhangqi, Xu Chenyu, Cao Peihua, Huang Guozhi

机构信息

Center of Rehabilitation Medicine, Zhujiang Hospital, Southern Medical University, Guangzhou, Guangdong, 510280, China.

School of Rehabilitation Sciences, Southern Medical University, Guangzhou, Guangdong, 510280, China.

出版信息

BMC Neurol. 2025 May 3;25(1):193. doi: 10.1186/s12883-025-04203-7.

DOI:10.1186/s12883-025-04203-7

PMID:40319228

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12049012/

Abstract

BACKGROUND

Lower limb exoskeleton rehabilitation robot is a new technology to improve the lower limb motor function of stroke patients. Recovery of motor function after stroke is closely related to neuroplasticity in the motor cortex and associated motor areas. However, few studies investigate how rehabilitation robots affect the neuroplasticity of stroke patients.This study sought to determine the effects of lower limb exoskeleton robot walking training on neuroplasticity and lower limb motor function in patients with stroke.

METHODS

A total of 25 (50.26 ± 11.42 years, 68.0% male) patients(age 18-75 years, onset between 2 weeks and 6 months) with a stable condition after having a stroke were randomized into a treatment (n = 13) and control group (n = 12). Bilateral Exoskeletal Assistive Robot H1 (BEAR-H1) walking training was provided to the treatment group, whereas conventional walking training was provided to the control group. Both groups completed two training sessions per day for 30 min each and were trained 5 days a week for 4 weeks. Transcranial magnetic stimulation, Fugl-Meyer Assessment lower extremity, Functional Ambulation Category 6-min walking distance test, intelligent gait analysis, and surface electromyography of the lower limbs were performed before and 4 weeks after treatment.

RESULTS

Both groups showed obvious improvements in all evaluation indicators (p < 0.05). Compared with the control group, the treatment group exhibited a decreased resting motor threshold and increased motor-evoked potential amplitude and recruitment curve slope (p < 0.05). The treatment group performed better than the control group (p < 0.05) in the 6-min walk test and knee flexion co-contraction ratio (CR). Correlation analysis showed that resting motor threshold, motor-evoked potential amplitude, and the recruitment curve slope were significantly correlated with the 6-min walk test, CR on ankle dorsiflexion, the root mean square of the tibialis anterior, biceps femoris, and medial gastrocnemius (p < 0.05).

CONCLUSION

Walking training using the bilateral exoskeletal assistive robot H1 improved cerebral cortical excitability in patients with stroke, which facilitated changes in neuroplasticity and enhanced lower limb motor function.

REGISTRATION

Chinese Clinical Trail Registry: ChiCTR1900028262. Registered Date: December 16,2019. Registration-URL: http://www.chictr.org.cn.

摘要

背景

下肢外骨骼康复机器人是一种改善中风患者下肢运动功能的新技术。中风后运动功能的恢复与运动皮层及相关运动区域的神经可塑性密切相关。然而，很少有研究探讨康复机器人如何影响中风患者的神经可塑性。本研究旨在确定下肢外骨骼机器人步行训练对中风患者神经可塑性和下肢运动功能的影响。

方法

将25例（年龄50.26±11.42岁，男性占68.0%）病情稳定的中风患者（年龄18 - 75岁，发病时间在2周和6个月之间）随机分为治疗组（n = 13）和对照组（n = 12）。治疗组接受双侧外骨骼辅助机器人H1（BEAR - H1）步行训练，而对照组接受传统步行训练。两组均每天完成2节训练课，每节30分钟，每周训练5天，共训练4周。在治疗前和治疗4周后进行经颅磁刺激、Fugl - Meyer评估下肢、功能性步行分类6分钟步行距离测试、智能步态分析以及下肢表面肌电图检查。

结果

两组在所有评估指标上均有明显改善（p < 0.05）。与对照组相比，治疗组静息运动阈值降低，运动诱发电位幅度和募集曲线斜率增加（p < 0.05）。治疗组在6分钟步行测试和膝关节屈曲共同收缩率（CR）方面表现优于对照组（p < 0.05）。相关性分析表明，静息运动阈值、运动诱发电位幅度和募集曲线斜率与6分钟步行测试、踝关节背屈时的CR、胫前肌、股二头肌和腓肠肌内侧头的均方根显著相关（p < 0.05）。