The Advantage of Low-Delta Electroencephalogram Phase Feature for Reconstructing the Center-Out Reaching Hand Movements

It is an emerging frontier of research on the use of neural signals for prosthesis control, in order to restore lost function to amputees and patients after spinal cord injury. Compared to the invasive neural signal based brain-machine interface (BMI), a non-invasive alternative, i.e., the electroencephalogram (EEG)-based BMI would be more widely accepted by the patients above. Ideally, a real-time continuous neuroprosthestic control is required for practical applications. However, conventional EEG-based BMIs mainly deal with the discrete brain activity classification. Until recently, the literature has reported several attempts for achieving the real-time continuous control by reconstructing the continuous movement parameters (e.g., speed, position, etc.) from the EEG recordings, and the low-frequency band EEG is consistently reported to encode the continuous motor control information. Previous studies with executed movement tasks have extensively relied on the amplitude representation of such slow oscillations of EEG signals for building models to decode kinematic parameters. Inspired by the recent successes of instantaneous phase of low-frequency invasive brain signals in the motor control and sensory processing domains, this study examines the extension of such a slow-oscillation phase representation to the reconstructing two-dimensional hand movements, with the non-invasive EEG signals for the first time. The data for analysis are collected on five healthy subjects performing 2D hand center-out reaching along four directions in two sessions. On representative channels over the cortices encoding the execution information of reaching movements, we show that the low-delta EEG phase representation is characterized by higher signal-to-noise ratio and stronger modulation by the movement tasks, compared to the low-delta EEG amplitude representation. Furthermore, we have tested the low-delta EEG phase representation with two commonly used linear decoding models. The results demonstrate that the low-delta EEG phase based decoders lead to superior performance for 2D executed movement reconstruction to its amplitude based counterparts, as well as the other-frequency band amplitude and power based features. Thus, our study contributes to improve the movement reconstruction from EEG by introducing a new feature set based on the low-delta EEG phase patterns, and demonstrates its potential for continuous fine motion control of neuroprostheses.

[1]  Nitish V. Thakor,et al.  Demonstration of a Semi-Autonomous Hybrid Brain–Machine Interface Using Human Intracranial EEG, Eye Tracking, and Computer Vision to Control a Robotic Upper Limb Prosthetic , 2014, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

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

[3]  Christian Bauckhage,et al.  Prediction of successful memory encoding based on single-trial rhinal and hippocampal phase information , 2016, NeuroImage.

[4]  Z. Gu,et al.  Decoding hand movement velocity from electroencephalogram signals during a drawing task , 2010, Biomedical engineering online.

[5]  Anca Radulescu,et al.  Neural Network Spectral Robustness under Perturbations of the Underlying Graph , 2016, Neural Computation.

[6]  Bin He,et al.  Noninvasive Electroencephalogram Based Control of a Robotic Arm for Reach and Grasp Tasks , 2016, Scientific Reports.

[7]  Trent J. Bradberry,et al.  Reconstructing Three-Dimensional Hand Movements from Noninvasive Electroencephalographic Signals , 2010, The Journal of Neuroscience.

[8]  Yuguo Yu,et al.  Decoding English Alphabet Letters Using EEG Phase Information , 2018, Front. Neurosci..

[9]  Dimitrios Pantazis,et al.  Coherent neural representation of hand speed in humans revealed by MEG imaging , 2007, Proceedings of the National Academy of Sciences.

[10]  C. Mehring,et al.  Encoding of Movement Direction in Different Frequency Ranges of Motor Cortical Local Field Potentials , 2005, The Journal of Neuroscience.

[11]  Wenwei Yu,et al.  Real-time Hand Motion Reconstruction System for Trans-Humeral Amputees Using EEG and EMG , 2016, Front. Robot. AI.

[12]  Tanja Schultz,et al.  Filling a glass of water: Continuously decoding the speed of 3D hand movements from EEG signals , 2012, 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[13]  D Coyle,et al.  3D hand motion trajectory prediction from EEG mu and beta bandpower. , 2016, Progress in brain research.

[14]  Chun-Yi Su,et al.  Brain–Machine Interface and Visual Compressive Sensing-Based Teleoperation Control of an Exoskeleton Robot , 2017, IEEE Transactions on Fuzzy Systems.

[15]  Andrew Y. Paek,et al.  Global cortical activity predicts shape of hand during grasping , 2015, Front. Neurosci..

[16]  A. P. Vinod,et al.  Noninvasive Brain-Computer Interface: Decoding Arm Movement Kinematics and Motor Control , 2016, IEEE Systems, Man, and Cybernetics Magazine.

[17]  Benedict Shien Wei Ng,et al.  EEG phase patterns reflect the selectivity of neural firing. , 2013, Cerebral cortex.

[18]  Andreas Schulze-Bonhage,et al.  Prediction of arm movement trajectories from ECoG-recordings in humans , 2008, Journal of Neuroscience Methods.

[19]  Hong Zeng,et al.  Discriminative spatial-frequency-temporal feature extraction and classification of motor imagery EEG: An sparse regression and Weighted Naïve Bayesian Classifier-based approach , 2017, Journal of Neuroscience Methods.

[20]  Aiguo Song,et al.  Optimizing Single-Trial EEG Classification by Stationary Matrix Logistic Regression in Brain–Computer Interface , 2016, IEEE Transactions on Neural Networks and Learning Systems.

[21]  Y. Höller,et al.  High Amplitude EEG Motor Potential during Repetitive Foot Movement: Possible Use and Challenges for Futuristic BCIs That Restore Mobility after Spinal Cord Injury , 2017, Front. Neurosci..

[22]  Andreea Ioana Sburlea,et al.  Advantages of EEG phase patterns for the detection of gait intention in healthy and stroke subjects , 2016, Journal of neural engineering.

[23]  Odelia Schwartz,et al.  Decoding of finger trajectory from ECoG using deep learning , 2018, Journal of neural engineering.

[24]  Cuntai Guan,et al.  Adaptive estimation of hand movement trajectory in an EEG based brain–computer interface system , 2015, Journal of neural engineering.

[25]  L. Paninski,et al.  Spatiotemporal tuning of motor cortical neurons for hand position and velocity. , 2004, Journal of neurophysiology.

[26]  Ting Li,et al.  Decoding Voluntary Movement of Single Hand Based on Analysis of Brain Connectivity by Using EEG Signals , 2018, Front. Hum. Neurosci..

[27]  José L Contreras-Vidal,et al.  Decoding three-dimensional hand kinematics from electroencephalographic signals , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[28]  Seong-Whan Lee,et al.  Decoding Three-Dimensional Trajectory of Executed and Imagined Arm Movements From Electroencephalogram Signals , 2015, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[29]  Damien Coyle,et al.  Decoding Imagined 3D Hand Movement Trajectories From EEG: Evidence to Support the Use of Mu, Beta, and Low Gamma Oscillations , 2018, Front. Neurosci..

[30]  Mahyar Hamedi,et al.  Electroencephalographic Motor Imagery Brain Connectivity Analysis for BCI: A Review , 2016, Neural Computation.

[31]  Jun Morimoto,et al.  Markov Switching Model for Quick Detection of Event Related Desynchronization in EEG , 2018, Front. Neurosci..

[32]  Aiguo Song,et al.  Investigation of Phase Features of Movement Related Cortical Potentials for Upper-Limb Movement Intention Detection , 2017, ICIRA.

[33]  A. Aertsen,et al.  The role of ECoG magnitude and phase in decoding position, velocity, and acceleration during continuous motor behavior , 2013, Front. Neurosci..

[34]  A. P. Georgopoulos,et al.  Neuronal population coding of movement direction. , 1986, Science.

[35]  S. Acharya,et al.  Connectivity Analysis as a Novel Approach to Motor Decoding for Prosthesis Control , 2012, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[36]  Wei Wu,et al.  Bayesian Population Decoding of Motor Cortical Activity Using a Kalman Filter , 2006, Neural Computation.

[37]  Aiguo Song,et al.  Closed-Loop Hybrid Gaze Brain-Machine Interface Based Robotic Arm Control with Augmented Reality Feedback , 2017, Front. Neurorobot..

[38]  R. Barry,et al.  EEG phase states at stimulus onset in a variable-ISI Go/NoGo task: Effects on ERP components , 2018, Biological Psychology.