EEG changes during passive movements improve the motor imagery feature extraction in BCIs-based sensory feedback calibration

Delisle-Rodríguez, Denis; Silva, Leticia; Filho, Teodiano Freire Bastos

doi:10.1088/1741-2552/acb73b

Cited by 9 publications

(6 citation statements)

References 30 publications

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“…This approach tested in a total of 12 sessions each one of 19 min in length, undoubtedly may be attractive for clinical practice, as it contributes optimizing therapies addressed to physically provide gait training by a robotic system, and also neurofeedback or BCI training. In our approach, gait MI and passive gait training are combined in Lokomat®, which agree with some studies suggesting that the combination of MI with passive movements may be attractive for upper limb or lower limb rehabilitation of individuals with severe motor impairments [29], [30]. In fact, Delisle et al, [30] observed that better lower-limb motor imagery features can be extracted using as a reference EEG changes from passive movements.…”

Section: Discussionsupporting

confidence: 82%

“…In our approach, gait MI and passive gait training are combined in Lokomat®, which agree with some studies suggesting that the combination of MI with passive movements may be attractive for upper limb or lower limb rehabilitation of individuals with severe motor impairments [29], [30]. In fact, Delisle et al, [30] observed that better lower-limb motor imagery features can be extracted using as a reference EEG changes from passive movements. Therefore, similar brain regions around the foot area (Cz) may be activated when an individuals received gait passive training in Lokomat®.…”

Section: Discussionsupporting

confidence: 82%

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Gait Training-Based Motor Imagery and EEG Neurofeedback in Lokomat: A Clinical Intervention With Complete Spinal Cord Injury Individuals

Serafini,

Guerrero-Mendez,

Bastos-Filho

et al. 2024

IEEE Trans. Neural Syst. Rehabil. Eng.

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Robotic systems, such as Lokomat® have shown promising results in people with severe motor impairments, who suffered a stroke or other neurological damage. Robotic devices have also been used by people with more challenging damages, such as Spinal Cord Injury (SCI), using feedback strategies that provide information about the brain activity in real-time. This study proposes a novel Motor Imagery (MI)-based Electroencephalogram (EEG) Visual Neurofeedback (VNFB) system for Loko-mat® to teach individuals how to modulate their own µ (8-12 Hz) and β (15-20 Hz) rhythms during passive walking. Two individuals with complete SCI tested our VNFB system completing a total of 12 sessions, each on different days. For evaluation, clinical outcomes before and after the intervention and brain connectivity were analyzed. As findings, the sensitivity related to light touch and painful discrimination increased for both individuals. Furthermore, an improvement in neurogenic bladder and bowel functions was observed according to the American Spinal Injury Association Impairment Scale, Neurogenic Bladder Symptom Score, and Gastrointestinal Symptom Rating Scale. Moreover, brain connectivity between different EEG locations significantly (p <0.05) increased, mainly in the motor cortex. As other highlight, both SCI individuals enhanced their µ rhythm, suggesting motor learning. These results indicate that our gait training approach may have substantial clinical benefits in complete SCI individuals.

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Section: Discussionsupporting

confidence: 82%

Section: Discussionsupporting

confidence: 82%

Gait Training-Based Motor Imagery and EEG Neurofeedback in Lokomat: A Clinical Intervention With Complete Spinal Cord Injury Individuals

Serafini,

Guerrero-Mendez,

Bastos-Filho

et al. 2024

IEEE Trans. Neural Syst. Rehabil. Eng.

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“…However, some related studies can be mentioned. For example, some studies have reported the use of CSP-based methods to classify upper-and lower-limb MI tasks, where Accs close to 0.75 have been achieved [23,36]. However, little is known about these algorithmic strategies in pedaling AM tasks, where it is possible to highlight that, in our study, it was possible to obtain an Acc close to 0.81.…”

Section: Discussionmentioning

confidence: 56%

“…Therefore, our findings make a contribution to the neuroscience community where we observed that pedaling tasks can be detected using EEG and machine learning-based techniques. Recently, our team has been interested in the study of neuroscience and BCIs with promising applicators to lower limbs rehabilitation using MMEBs [5,18,28,36]. However, one of the limitations identified from this work was that a real-time BCI was not implemented to classify pedaling tasks with an end-effector, which may limit the scope of our results.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of temporal, spatial and spectral filtering in CSP-based methods for decoding pedaling-based motor tasks using EEG signals

Blanco-Díaz,

Guerrero-Mendez,

Delisle-Rodriguez

et al. 2024

Biomed. Phys. Eng. Express

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Stroke is a neurological syndrome that usually causes a loss of voluntary control of lower/upper body movements, making it difficult for affected individuals to perform Activities of Daily Living (ADLs). Brain-Computer Interfaces (BCIs) combined with robotic systems, such as Motorized Mini Exercise Bikes (MMEB), have enabled the rehabilitation of people with disabilities by decoding their actions and executing a motor task. However, Electroencephalography (EEG)-based BCIs are affected by the presence of physiological and non-physiological artifacts. Thus, movement discrimination using EEG become challenging, even in pedaling tasks, which have not been well explored in the literature. In this study, Common Spatial Patterns (CSP)-based methods were proposed to classify pedaling motor tasks. To address this, Filter Bank Common Spatial Patterns (FBCSP) and Filter Bank Common Spatial-Spectral Patterns (FBCSSP) were implemented with different spatial filtering configurations by varying the time segment with different filter bank combinations for the three methods to decode pedaling tasks. An in-house EEG dataset during pedaling tasks was registered for 8 participants. As results, the best configuration corresponds to a filter bank with two filters (8–19 Hz and 19–30 Hz) using a time window between 1.5 and 2.5 s after the cue and implementing two spatial filters, which provide accuracy of approximately 0.81, False Positive Rates lower than 0.19, and \textit{Kappa} index of 0.61. This work implies that EEG oscillatory patterns during pedaling can be accurately classified using machine learning. Therefore, our method can be applied in the rehabilitation context, such as MMEB-based BCIs, in the future.

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“…The proposed method integrates cutting-edge technologies including tDCS, MI-BCI, VR, and a customized MP to facilitate the lower-limb rehabilitation of post-stroke patients. This innovative system also introduces a novel approach to BCI calibration, combining EEG signals from both MI and actual movements [19], fostering a real-time closed-loop system for neural rehabilitation. Furthermore, the study highlights the potential benefits and cost-effectiveness of tDCS in inducing cortical plasticity for motor recovery in lower-limb rehabilitation, aiming to mitigate neuromuscular disabilities and associated societal costs.…”

Section: Introductionmentioning

confidence: 99%

Unraveling Transformative Effects after tDCS and BCI Intervention in Chronic Post-Stroke Patient Rehabilitation—An Alternative Treatment Design Study

Lima,

Silva,

Delisle-Rodriguez

et al. 2023

Sensors

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Stroke is a debilitating clinical condition resulting from a brain infarction or hemorrhage that poses significant challenges for motor function restoration. Previous studies have shown the potential of applying transcranial direct current stimulation (tDCS) to improve neuroplasticity in patients with neurological diseases or disorders. By modulating the cortical excitability, tDCS can enhance the effects of conventional therapies. While upper-limb recovery has been extensively studied, research on lower limbs is still limited, despite their important role in locomotion, independence, and good quality of life. As the life and social costs due to neuromuscular disability are significant, the relatively low cost, safety, and portability of tDCS devices, combined with low-cost robotic systems, can optimize therapy and reduce rehabilitation costs, increasing access to cutting-edge technologies for neuromuscular rehabilitation. This study explores a novel approach by utilizing the following processes in sequence: tDCS, a motor imagery (MI)-based brain-computer interface (BCI) with virtual reality (VR), and a motorized pedal end-effector. These are applied to enhance the brain plasticity and accelerate the motor recovery of post-stroke patients. The results are particularly relevant for post-stroke patients with severe lower-limb impairments, as the system proposed here provides motor training in a real-time closed-loop design, promoting cortical excitability around the foot area (Cz) while the patient directly commands with his/her brain signals the motorized pedal. This strategy has the potential to significantly improve rehabilitation outcomes. The study design follows an alternating treatment design (ATD), which involves a double-blind approach to measure improvements in both physical function and brain activity in post-stroke patients. The results indicate positive trends in the motor function, coordination, and speed of the affected limb, as well as sensory improvements. The analysis of event-related desynchronization (ERD) from EEG signals reveals significant modulations in Mu, low beta, and high beta rhythms. Although this study does not provide conclusive evidence for the superiority of adjuvant mental practice training over conventional therapy alone, it highlights the need for larger-scale investigations.

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EEG changes during passive movements improve the motor imagery feature extraction in BCIs-based sensory feedback calibration

Cited by 9 publications

References 30 publications

Gait Training-Based Motor Imagery and EEG Neurofeedback in Lokomat: A Clinical Intervention With Complete Spinal Cord Injury Individuals

Gait Training-Based Motor Imagery and EEG Neurofeedback in Lokomat: A Clinical Intervention With Complete Spinal Cord Injury Individuals

Evaluation of temporal, spatial and spectral filtering in CSP-based methods for decoding pedaling-based motor tasks using EEG signals

Unraveling Transformative Effects after tDCS and BCI Intervention in Chronic Post-Stroke Patient Rehabilitation—An Alternative Treatment Design Study

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