Anticipatory Detection of Self-Paced Rehabilitative Movements in the Same Upper Limb From EEG Signals

Currently, one of the challenges in EEG-based brain-computer interfaces (BCI) for neurorehabilitation is the recognition of the intention to perform different movements from the same limb. This would allow finer control of neurorehabilitation and motor recovery devices by end-users. To address this issue, we assess the feasibility of recognizing two rehabilitative right upper-limb movements from pre-movement EEG signals. These rehabilitative movements were performed self-selected and self-initiated by the users using a motor rehabilitation robotic device. This work proposes anticipatory detection scenarios that discriminate EEG signals corresponding to non-movement state and movement intentions of two same-limb movements. The studied movements were discriminated above the empirical chance levels for all proposed detection scenarios. Percentages of correctly anticipated trials ranged from 64.3% to 77.0%, and the detection times ranged from 620 to 300 ms prior to movement initiation. The results of these studies indicate that it is possible to detect the intention to perform two different movements of the same upper limb and non-movement state. Based on these results, the decoding of the movement intention could potentially be used to develop more natural and intuitive robot-assisted neurorehabilitation therapies.

[1]  Berenice Gudiño-Mendoza,et al.  Detecting the Intention to Move Upper Limbs from Electroencephalographic Brain Signals , 2016, Comput. Math. Methods Medicine.

[2]  Jessica Cantillo-Negrete,et al.  Motor Imagery-Based Brain-Computer Interface Coupled to a Robotic Hand Orthosis Aimed for Neurorehabilitation of Stroke Patients , 2018, Journal of healthcare engineering.

[3]  Ander Ramos-Murguialday,et al.  Classification of different reaching movements from the same limb using EEG , 2017, Journal of neural engineering.

[4]  Bernhard Graimann,et al.  Quantification and visualization of event-related changes in oscillatory brain activity in the time-frequency domain. , 2006, Progress in brain research.

[5]  Seong-Whan Lee,et al.  Comparative analysis of features extracted from EEG spatial, spectral and temporal domains for binary and multiclass motor imagery classification , 2019, Inf. Sci..

[6]  Christa Neuper,et al.  Rehabilitation with Brain-Computer Interface Systems , 2008, Computer.

[7]  Jan Peters,et al.  Predicting motor learning performance from Electroencephalographic data , 2014, Journal of NeuroEngineering and Rehabilitation.

[8]  Daniel M Wolpert,et al.  Imagery of movements immediately following performance allows learning of motor skills that interfere , 2018, Scientific Reports.

[9]  Gernot R Müller-Putz,et al.  Upper limb movements can be decoded from the time-domain of low-frequency EEG , 2017, PloS one.

[10]  Cheng Yee Low,et al.  Classification of Electroencephalogram Data from Hand Grasp and Release Movements for BCI Controlled Prosthesis , 2016 .

[11]  Marc M. Van Hulle,et al.  Comparison of Classification Methods for P300 Brain-Computer Interface on Disabled Subjects , 2011, Comput. Intell. Neurosci..

[12]  Dennis J. McFarland,et al.  Brain–computer interfaces for communication and control , 2002, Clinical Neurophysiology.

[13]  Moritz Grosse-Wentrup,et al.  Using brain–computer interfaces to induce neural plasticity and restore function , 2011, Journal of neural engineering.

[14]  N. Birbaumer,et al.  BCI2000: a general-purpose brain-computer interface (BCI) system , 2004, IEEE Transactions on Biomedical Engineering.

[15]  Vera Kaiser,et al.  First Steps Toward a Motor Imagery Based Stroke BCI: New Strategy to Set up a Classifier , 2011, Front. Neurosci..

[16]  Javier Mauricio Antelis,et al.  Self-paced movement intention recognition from EEG signals during upper limb robot-assisted rehabilitation , 2019, 2019 9th International IEEE/EMBS Conference on Neural Engineering (NER).

[17]  Á. Gil-Agudo,et al.  Continuous decoding of movement intention of upper limb self-initiated analytic movements from pre-movement EEG correlates , 2014, Journal of NeuroEngineering and Rehabilitation.

[18]  Rajesh P. N. Rao,et al.  Cortical activity during motor execution, motor imagery, and imagery-based online feedback , 2010, Proceedings of the National Academy of Sciences.

[19]  G R Müller-Putz,et al.  From classic motor imagery to complex movement intention decoding: The noninvasive Graz-BCI approach. , 2016, Progress in brain research.

[20]  Miguel A. L. Nicolelis,et al.  Brain–machine interfaces: past, present and future , 2006, Trends in Neurosciences.

[21]  Kezhong Zhang,et al.  A Review on Electroencephalogram Based Brain Computer Interface for Elderly Disabled , 2019, IEEE Access.

[22]  Javaid Iqbal,et al.  Design of Embedded System for Multivariate Classification of Finger and Thumb Movements Using EEG Signals for Control of Upper Limb Prosthesis , 2018, BioMed research international.

[23]  J. Millán,et al.  Brain‐computer interfaces for post‐stroke motor rehabilitation: a meta‐analysis , 2018, Annals of clinical and translational neurology.

[24]  Cuntai Guan,et al.  Brain–Computer Interface for Neurorehabilitation of Upper Limb After Stroke , 2015, Proceedings of the IEEE.

[25]  Omar Aguilar-Leal,et al.  Platform for the study of virtual task-oriented motion and its evaluation by EEG and EMG biopotentials , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[26]  Monica A. Perez,et al.  Neural interface technology for rehabilitation: exploiting and promoting neuroplasticity. , 2010, Physical medicine and rehabilitation clinics of North America.

[27]  J. Pernier,et al.  Oscillatory γ-Band (30–70 Hz) Activity Induced by a Visual Search Task in Humans , 1997, The Journal of Neuroscience.

[28]  Lev Stankevich,et al.  Development of electroencephalographic pattern classifiers for real and imaginary thumb and index finger movements of one hand , 2015, Artif. Intell. Medicine.

[29]  Robert Oostenveld,et al.  FieldTrip: Open Source Software for Advanced Analysis of MEG, EEG, and Invasive Electrophysiological Data , 2010, Comput. Intell. Neurosci..

[30]  J. Wolpaw,et al.  Brain–computer interfaces in neurological rehabilitation , 2008, The Lancet Neurology.

[31]  Mahdi Bamdad,et al.  Application of BCI systems in neurorehabilitation: a scoping review , 2015, Disability and rehabilitation. Assistive technology.

[32]  O. Solomon,et al.  PSD computations using Welch's method , 1991 .

[33]  A. Frolov,et al.  Motor Imagery and Its Practical Application , 2014, Neuroscience and Behavioral Physiology.

[34]  Carlo Menon,et al.  EEG Classification of Different Imaginary Movements within the Same Limb , 2015, PloS one.

[35]  J. Pereira,et al.  Decoding natural reach-and-grasp actions from human EEG , 2018, Journal of neural engineering.

[36]  William Stafford Noble,et al.  Support vector machine , 2013 .

[37]  G. Pfurtscheller,et al.  Motor imagery activates primary sensorimotor area in humans , 1997, Neuroscience Letters.

[38]  Aleksandra Vučković,et al.  A two-stage four-class BCI based on imaginary movements of the left and the right wrist. , 2012, Medical engineering & physics.

[39]  Russ Greiner,et al.  Assessment of feature selection and classification methods for recognizing motor imagery tasks from electroencephalographic signals , 2016, Artif. Intell. Res..

[40]  G. Baudat,et al.  Generalized Discriminant Analysis Using a Kernel Approach , 2000, Neural Computation.

[41]  Brendan Z. Allison,et al.  Brain-Computer Interfaces: Revolutionizing Human-Computer Interaction , 2013 .

[42]  Chee Siang Ang,et al.  Use of brain computer interfaces in neurological rehabilitation , 2011 .

[43]  Carlo Menon,et al.  Classifying three imaginary states of the same upper extremity using time-domain features , 2017, PloS one.

[44]  Klaus-Robert Müller,et al.  Combined Optimization of Spatial and Temporal Filters for Improving Brain-Computer Interfacing , 2006, IEEE Transactions on Biomedical Engineering.

[45]  L. Cohen,et al.  Brain–machine interfaces in neurorehabilitation of stroke , 2015, Neurobiology of Disease.

[46]  O M Solomon,et al.  PSD computations using Welch's method. [Power Spectral Density (PSD)] , 1991 .

[47]  M Congedo,et al.  A review of classification algorithms for EEG-based brain–computer interfaces: a 10 year update , 2018, Journal of neural engineering.

[48]  F. L. D. Silva,et al.  Event-related EEG/MEG synchronization and desynchronization: basic principles , 1999, Clinical Neurophysiology.

[49]  J. Pineda The functional significance of mu rhythms: Translating “seeing” and “hearing” into “doing” , 2005, Brain Research Reviews.

[50]  Marcia A. Bockbrader,et al.  Brain Computer Interfaces in Rehabilitation Medicine , 2018, PM & R : the journal of injury, function, and rehabilitation.

[51]  C. Neuper,et al.  Combining Brain–Computer Interfaces and Assistive Technologies: State-of-the-Art and Challenges , 2010, Front. Neurosci..

[52]  G. Pfurtscheller,et al.  Evaluation of event-related desynchronization (ERD) preceding and following voluntary self-paced movement. , 1979, Electroencephalography and clinical neurophysiology.

[53]  J. Millán,et al.  Single trial prediction of self-paced reaching directions from EEG signals , 2014, Front. Neurosci..

[54]  Ke Liao,et al.  Decoding Individual Finger Movements from One Hand Using Human EEG Signals , 2014, PloS one.

[55]  José del R. Millán,et al.  Motor Attempt EEG Paradigm as a Diagnostic Tool for Disorders of Consciousness , 2018, 2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).