SSVEP-Based Brain Computer Interface Controlled Soft Robotic Glove for Post-Stroke Hand Function Rehabilitation

Soft robotic glove with brain computer interfaces (BCI) control has been used for post-stroke hand function rehabilitation. Motor imagery (MI) based BCI with robotic aided devices has been demonstrated as an effective neural rehabilitation tool to improve post-stroke hand function. It is necessary f...

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Bibliographic Details
Published inIEEE transactions on neural systems and rehabilitation engineering Vol. 30; p. 1
Main Authors Guo, Ning, Wang, Xiaojun, Duanmu, Dehao, Huang, Xin, Li, Xiaodong, Fan, Yunli, Li, Hailan, Liu, Yongquan, Yeung, Eric Hiu Kwong, To, Michael Kai Tsun, Gu, Jianxiong, Wan, Feng, Hu, Yong
Format Journal Article
LanguageEnglish
Published New York IEEE 2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Brain
Brain computer interfaces (BCI)
Computer applications
Elbow
Elbow (anatomy)
Electroencephalography
End effectors
Hand
Hand (anatomy)
hand rehabilitation
Human-computer interface
Implants
Interfaces
Medical treatment
Mental task performance
post stroke
Rehabilitation
Robot kinematics
Robotics
Robots
Soft robotic glove
Soft robotics
steady-state visually evoked potentials (SSVEP)
Stroke
Stroke (medical condition)
Training
Wrist
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Summary:Soft robotic glove with brain computer interfaces (BCI) control has been used for post-stroke hand function rehabilitation. Motor imagery (MI) based BCI with robotic aided devices has been demonstrated as an effective neural rehabilitation tool to improve post-stroke hand function. It is necessary for a user of MI-BCI to receive a long time training, while the user usually suffers unsuccessful and unsatisfying results in the beginning. To propose another non-invasive BCI paradigm rather than MI-BCI, steady-state visually evoked potentials (SSVEP) based BCI was proposed as user intension detection to trigger the soft robotic glove for post-stroke hand function rehabilitation. Thirty post-stroke patients with impaired hand function were randomly and equally divided into three groups to receive conventional, robotic, and BCI-robotic therapy in this randomized control trial (RCT). Clinical assessment of Fugl-Meyer Motor Assessment of Upper Limb (FMA-UL), Wolf Motor Function Test (WMFT) and Modified Ashworth Scale (MAS) were performed at pre-training, post-training and three months follow-up. In comparing to other groups, The BCI-robotic group showed significant improvement after training in FMA full score (10.05±8.03, p=0.001), FMA shoulder/elbow (6.2±5.94, p=0.0004) and FMA wrist/hand (4.3±2.83, p=0.007), and WMFT (5.1±5.53, p=0.037). The improvement of FMA was significantly correlated with BCI accuracy (r=0.714, p=0.032). Recovery of hand function after rehabilitation of SSVEP-BCI controlled soft robotic glove showed better result than solely robotic glove rehabilitation, equivalent efficacy as results from previous reported MI-BCI robotic hand rehabilitation. It proved the feasibility of SSVEP-BCI controlled soft robotic glove in post-stroke hand function rehabilitation.
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ISSN:1534-4320
1558-0210
1558-0210
DOI:10.1109/TNSRE.2022.3185262