Detecting the Intention to Move Upper Limbs from Electroencephalographic Brain Signals

Early decoding of motor states directly from the brain activity is essential to develop brain-machine interfaces (BMI) for natural motor control of neuroprosthetic devices. Hence, this study aimed to investigate the detection of movement information before the actual movement occurs. This information piece could be useful to provide early control signals to drive BMI-based rehabilitation and motor assisted devices, thus providing a natural and active rehabilitation therapy. In this work, electroencephalographic (EEG) brain signals from six healthy right-handed participants were recorded during self-initiated reaching movements of the upper limbs. The analysis of these EEG traces showed that significant event-related desynchronization is present before and during the execution of the movements, predominantly in the motor-related α and β frequency bands and in electrodes placed above the motor cortex. This oscillatory brain activity was used to continuously detect the intention to move the limbs, that is, to identify the motor phase prior to the actual execution of the reaching movement. The results showed, first, significant classification between relax and movement intention and, second, significant detection of movement intention prior to the onset of the executed movement. On the basis of these results, detection of movement intention could be used in BMI settings to reduce the gap between mental motor processes and the actual movement performed by an assisted or rehabilitation robotic device.

[1]  Gernot R. Müller-Putz,et al.  Self-Paced (Asynchronous) BCI Control of a Wheelchair in Virtual Environments: A Case Study with a Tetraplegic , 2007, Comput. Intell. Neurosci..

[2]  Piet M. T. Broersen,et al.  Autoregressive spectral estimation by application of the Burg algorithm to irregularly sampled data , 2002, IEEE Trans. Instrum. Meas..

[3]  D. Farina,et al.  Detection of movement intention from single-trial movement-related cortical potentials , 2011, 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]  Brendan Z. Allison,et al.  Brain-Computer Interfaces: Revolutionizing Human-Computer Interaction , 2013 .

[6]  Jonathan R Wolpaw,et al.  Sensorimotor rhythm-based brain–computer interface (BCI): model order selection for autoregressive spectral analysis , 2008, Journal of neural engineering.

[7]  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.

[8]  Dario Farina,et al.  Detection of movement-related cortical potentials based on subject-independent training , 2013, Medical & Biological Engineering & Computing.

[9]  Angelo Perkusich,et al.  BCI-aware pervasive multimedia for motor disabled people , 2010, 2010 International Conference on Information Society.

[10]  W. A. Sarnacki,et al.  Electroencephalographic (EEG) control of three-dimensional movement , 2010, Journal of neural engineering.

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

[12]  Corinna Cortes,et al.  Support-Vector Networks , 1995, Machine Learning.

[13]  G. Pfurtscheller,et al.  EEG-based neuroprosthesis control: A step towards clinical practice , 2005, Neuroscience Letters.

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

[15]  C.W. Anderson,et al.  Comparison of linear, nonlinear, and feature selection methods for EEG signal classification , 2003, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

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

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

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

[19]  M Congedo,et al.  A review of classification algorithms for EEG-based brain–computer interfaces , 2007, Journal of neural engineering.

[20]  Dawn M. Taylor,et al.  Extracting Attempted Hand Movements from EEGs in People with Complete Hand Paralysis Following Stroke , 2011, Front. Neurosci..

[21]  José Luis Pons Rovira,et al.  Predictive classification of self-paced upper-limb analytical movements with EEG , 2015, Medical & Biological Engineering & Computing.

[22]  Klaus-Robert Müller,et al.  Adaptive Methods in BCI Research - An Introductory Tutorial , 2009 .

[23]  Jonathan Becedas,et al.  Brain–Machine Interfaces: Basis and Advances , 2012, IEEE Transactions on Systems, Man, and Cybernetics, Part C (Applications and Reviews).

[24]  Anton Nijholt,et al.  Towards Practical Brain-Computer Interfaces: Bridging the Gap from Research to Real-World Applications , 2012 .

[25]  Mathew Salvaris,et al.  Decoding Intention at Sensorimotor Timescales , 2014, PloS one.

[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]  Usama M. Fayyad,et al.  Multi-Interval Discretization of Continuous-Valued Attributes for Classification Learning , 1993, IJCAI.

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

[30]  Michael I. Jordan,et al.  Beyond Independent Components: Trees and Clusters , 2003, J. Mach. Learn. Res..

[31]  J. Millán,et al.  Detection of self-paced reaching movement intention from EEG signals , 2012, Front. Neuroeng..

[32]  Chih-Jen Lin,et al.  LIBSVM: A library for support vector machines , 2011, TIST.

[33]  Huan Liu,et al.  Efficient Feature Selection via Analysis of Relevance and Redundancy , 2004, J. Mach. Learn. Res..

[34]  José del R. Millán,et al.  Towards Independence: A BCI Telepresence Robot for People With Severe Motor Disabilities , 2015, Proceedings of the IEEE.

[35]  M. Hallett,et al.  Classifying EEG signals preceding right hand, left hand, tongue, and right foot movements and motor imageries , 2008, Clinical Neurophysiology.

[36]  L. Cohen,et al.  Brain–computer interfaces: communication and restoration of movement in paralysis , 2007, The Journal of physiology.