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A novel, robust, and portable platform for magnetoencephalography using optically-pumped magnetometers

Schofield, Holly; Hill, Ryan M.; Feys, Odile; Holmes, Niall; Osborne, James; Doyle, Cody; Bobela, David; Corvilain, Pierre; Wens, Vincent; Rier, Lukas; Bowtell, Richard; Ferez, Maxime; Mullinger, Karen J.; Coleman, Sebastian; Rhodes, Natalie; Rea, Molly; Tanner, Zoe; Boto, Elena; de Tiège, Xavier; Shah, Vishal; Brookes, Matthew J.

A novel, robust, and portable platform for magnetoencephalography using optically-pumped magnetometers Thumbnail


Authors

Holly Schofield

Profile image of RYAN HILL

RYAN HILL RYAN.HILL@NOTTINGHAM.AC.UK
Senior Research Fellow

Odile Feys

NIALL HOLMES NIALL.HOLMES@NOTTINGHAM.AC.UK
Mansfield Research Fellow

James Osborne

Cody Doyle

David Bobela

Pierre Corvilain

Vincent Wens

Maxime Ferez

Sebastian Coleman

Natalie Rhodes

Molly Rea

Zoe Tanner

Xavier de Tiège

Vishal Shah



Abstract

Magnetoencephalography (MEG) measures brain function via assessment of magnetic fields generated by neural currents. Conventional MEG uses superconducting sensors, which place significant limitations on performance, practicality, and deployment; however, the field has been revolutionised in recent years by the introduction of optically-pumped-magnetometers (OPMs). OPMs enable measurement of the MEG signal without cryogenics, and consequently the conception of ‘OPM-MEG’ systems which ostensibly allow increased sensitivity and resolution, lifespan compliance, free subject movement, and lower cost. However, OPM-MEG is in its infancy with existing limitations on both sensor and system design. Here, we report a new OPM-MEG design with miniaturised and integrated electronic control, a high level of portability, and improved sensor dynamic range. We show that this system produces equivalent measures compared to an established OPM-MEG instrument; specifically, when measuring task-induced beta-band, gamma-band and evoked neuro-electrical responses, source localisations from the two systems were comparable and temporal correlation of measured brain responses was >0.7 at the individual level and >0.9 for groups. Using an electromagnetic phantom, we demonstrate improved dynamic range by running the system in background fields up to 8 nT. We show that the system is effective in gathering data during free movement (including a sitting-to-standing paradigm) and that it is compatible with simultaneous electroencephalography (EEG). Finally, we demonstrate portability by moving the system between two laboratories. Overall, our new system is shown to be a significant step forward for OPM-MEG and offers an attractive platform for next generation functional medical imaging.

Citation

Schofield, H., Hill, R. M., Feys, O., Holmes, N., Osborne, J., Doyle, C., Bobela, D., Corvilain, P., Wens, V., Rier, L., Bowtell, R., Ferez, M., Mullinger, K. J., Coleman, S., Rhodes, N., Rea, M., Tanner, Z., Boto, E., de Tiège, X., Shah, V., & Brookes, M. J. (2024). A novel, robust, and portable platform for magnetoencephalography using optically-pumped magnetometers. Imaging Neuroscience, 2, 1-22. https://doi.org/10.1162/imag_a_00283

Journal Article Type Article
Acceptance Date Jul 29, 2024
Online Publication Date Aug 20, 2024
Publication Date Aug 20, 2024
Deposit Date Oct 21, 2024
Publicly Available Date Oct 21, 2024
Journal Imaging Neuroscience
Print ISSN 2837-6056
Electronic ISSN 2837-6056
Publisher Massachusetts Institute of Technology Press
Peer Reviewed Peer Reviewed
Volume 2
Pages 1-22
DOI https://doi.org/10.1162/imag_a_00283
Keywords optically-pumped magnetometer, OPM, magnetoencephalography, MEG, electrophysiology
Public URL https://nottingham-repository.worktribe.com/output/39160117
Publisher URL https://direct.mit.edu/imag/article/doi/10.1162/imag_a_00283/124093/A-novel-robust-and-portable-platform-for

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