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Towards decoding speech production from single-trial magnetoencephalography (MEG) signals

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Abstract:

Patients with locked-in-syndrome (fully paralyzed but aware) struggle in their life and communication. Providing a level of communication offers these patients a chance t...Show More

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Abstract:

Patients with locked-in-syndrome (fully paralyzed but aware) struggle in their life and communication. Providing a level of communication offers these patients a chance to resume a meaningful life. Current brain-computer interface (BCI) communication requires users to build words from single letters selected on a screen, which is extremely inefficient. Faster approaches for their speech communication are highly needed. This project investigated the possibility to decode spoken phrases from non-invasive brain activity (MEG) signals. This direct brain-to-text mapping approach may provide a significantly faster communication rate than current BCIs can provide. We used dynamic time warping and Wiener filtering for noise reduction and then Gaussian mixture model and artificial neural network as the decoders. Preliminary results showed the possibility of decoding speech production from non-invasive brain signals. The best phrase classification accuracy was up to 94.54% from single-trial whole-head MEG recordings.

Published in: 2017 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

Date of Conference: 05-09 March 2017

Date Added to IEEE Xplore: 19 June 2017

ISBN Information:

Electronic ISSN: 2379-190X

DOI: 10.1109/ICASSP.2017.7952714

Conference Location: New Orleans, LA, USA

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Contents

1. Introduction

Brain damage or neurodegenerative disease (e.g., amyotrophic lateral sclerosis) may cause locked-in syndrome (fully paralyzed but aware) [1]. There is an incidence rate 0.7/10,000 for locked-in syndrome [2]. Patients with locked-in-struggle in their life and communication. Providing a level of communication offers these patients a chance to resume a meaningful life [3]. Brain activity may be the only pathway to facilitate the operation, control, and communication for these patients, because it bypasses the motor control mechanisms [4]–[7].

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Debadatta Dash, Paul Ferrari, Abbas Babajani-Feremi, Amir Borna, Peter D. D. Schwindt, Jun Wang, "Magnetometers vs Gradiometers for Neural Speech Decoding", 2021 43rd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC), pp.6543-6546, 2021.

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Debadatta Dash, Alan Wisler, Paul Ferrari, Elizabeth Moody Davenport, Joseph Maldjian, Jun Wang, "MEG Sensor Selection for Neural Speech Decoding", IEEE Access, vol.8, pp.182320-182337, 2020.

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Debadatta Dash, Paul Ferrari, Jun Wang, "Decoding Speech Evoked Jaw Motion from Non-invasive Neuromagnetic Oscillations", 2020 International Joint Conference on Neural Networks (IJCNN), pp.1-8, 2020.

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Debadatta Dash, Paul Ferrari, Saleem Malik, Jun Wang, "OVERT SPEECH RETRIEVAL FROM NEUROMAGNETIC SIGNALS USING WAVELETS AND ARTIFICIAL NEURAL NETWORKS", 2018 IEEE Global Conference on Signal and Information Processing (GlobalSIP), pp.489-493, 2018.

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Cites in Papers - Other Publishers (7)

Maxime Verwoert, Maarten C. Ottenhoff, Sophocles Goulis, Albert J. Colon, Louis Wagner, Simon Tousseyn, Johannes P. van Dijk, Pieter L. Kubben, Christian Herff, "Dataset of Speech Production in intracranial Electroencephalography", Scientific Data, vol.9, no.1, 2022.

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Jesse A Livezey, Joshua I Glaser, "Deep learning approaches for neural decoding across architectures and recording modalities", Briefings in Bioinformatics, vol.22, no.2, pp.1577, 2021.

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Debadatta Dash, Paul Ferrari, Satwik Dutta, Jun Wang, "NeuroVAD: Real-Time Voice Activity Detection from Non-Invasive Neuromagnetic Signals", Sensors, vol.20, no.8, pp.2248, 2020.

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Debadatta Dash, Paul Ferrari, Jun Wang, "Decoding Imagined and Spoken Phrases From Non-invasive Neural (MEG) Signals", Frontiers in Neuroscience, vol.14, 2020.

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Debadatta Dash, Paul Ferrari, Saleem Malik, Albert Montillo, Joseph A. Maldjian, Jun Wang, "Determining the Optimal Number of MEG Trials: A Machine Learning and Speech Decoding Perspective", Brain Informatics, vol.11309, pp.163, 2018.

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Josh Chartier, Gopala K. Anumanchipalli, Keith Johnson, Edward F. Chang, "Encoding of Articulatory Kinematic Trajectories in Human Speech Sensorimotor Cortex", Neuron, vol.98, no.5, pp.1042, 2018.

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Towards decoding speech production from single-trial magnetoencephalography (MEG) signals

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Abstract:

1. Introduction

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Cites in Papers - Other Publishers (7)

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Towards decoding speech production from single-trial magnetoencephalography (MEG) signals

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Abstract:

Metadata

Abstract:

1. Introduction

Cites in Papers - IEEE (4) | Other Publishers (7)

Cites in Papers - IEEE (4)

Cites in Papers - Other Publishers (7)

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