Sensors (Apr 2022)

Performance Analysis of Optically Pumped <sup>4</sup>He Magnetometers vs. Conventional SQUIDs: From Adult to Infant Head Models

  • Saeed Zahran,
  • Mahdi Mahmoudzadeh,
  • Fabrice Wallois,
  • Nacim Betrouni,
  • Philippe Derambure,
  • Matthieu Le Prado,
  • Agustin Palacios-Laloy,
  • Etienne Labyt

DOI
https://doi.org/10.3390/s22083093
Journal volume & issue
Vol. 22, no. 8
p. 3093

Abstract

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Optically pumped magnetometers (OPMs) are new, room-temperature alternatives to superconducting quantum interference devices (SQUIDs) for measuring the brain’s magnetic fields. The most used OPM in MagnetoEncephaloGraphy (MEG) are based on alkali atoms operating in the spin-exchange relaxation-free (SERF) regime. These sensors do not require cooling but have to be heated. Another kind of OPM, based on the parametric resonance of 4He atoms are operated at room temperature, suppressing the heat dissipation issue. They also have an advantageous bandwidth and dynamic range more suitable for MEG recordings. We quantitatively assessed the improvement (relative to a SQUID magnetometers array) in recording the magnetic field with a wearable 4He OPM-MEG system through data simulations. The OPM array and magnetoencephalography forward models were based on anatomical MRI data from an adult, a nine-year-old child, and 10 infants aged between one month and two years. Our simulations showed that a 4He OPMs array offers markedly better spatial specificity than a SQUID magnetometers array in various key performance areas (e.g., signal power, information content, and spatial resolution). Our results are also discussed regarding previous simulation results obtained for alkali OPM.

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