Sensors (Mar 2023)

A New Generation of OPM for High Dynamic and Large Bandwidth MEG: The <sup>4</sup>He OPMs—First Applications in Healthy Volunteers

  • Tjerk P. Gutteling,
  • Mathilde Bonnefond,
  • Tommy Clausner,
  • Sébastien Daligault,
  • Rudy Romain,
  • Sergey Mitryukovskiy,
  • William Fourcault,
  • Vincent Josselin,
  • Matthieu Le Prado,
  • Agustin Palacios-Laloy,
  • Etienne Labyt,
  • Julien Jung,
  • Denis Schwartz

DOI
https://doi.org/10.3390/s23052801
Journal volume & issue
Vol. 23, no. 5
p. 2801

Abstract

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MagnetoEncephaloGraphy (MEG) provides a measure of electrical activity in the brain at a millisecond time scale. From these signals, one can non-invasively derive the dynamics of brain activity. Conventional MEG systems (SQUID-MEG) use very low temperatures to achieve the necessary sensitivity. This leads to severe experimental and economical limitations. A new generation of MEG sensors is emerging: the optically pumped magnetometers (OPM). In OPM, an atomic gas enclosed in a glass cell is traversed by a laser beam whose modulation depends on the local magnetic field. MAG4Health is developing OPMs using Helium gas (4He-OPM). They operate at room temperature with a large dynamic range and a large frequency bandwidth and output natively a 3D vectorial measure of the magnetic field. In this study, five 4He-OPMs were compared to a classical SQUID-MEG system in a group of 18 volunteers to evaluate their experimental performances. Considering that the 4He-OPMs operate at real room temperature and can be placed directly on the head, our assumption was that 4He-OPMs would provide a reliable recording of physiological magnetic brain activity. Indeed, the results showed that the 4He-OPMs showed very similar results to the classical SQUID-MEG system by taking advantage of a shorter distance to the brain, despite having a lower sensitivity.

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