A 90‐channel triaxial magnetoencephalography system using optically pumped magnetometers

Rea, Molly; Boto, Elena; Holmes, Niall; Hill, Ryan M.; Osborne, James; Rhodes, Natalie; Leggett, James; Rier, Lukas; Bowtell, Richard; Shah, Vishal; Brookes, Matthew J.

doi:10.1111/nyas.14890

Cited by 53 publications

(41 citation statements)

References 76 publications

(151 reference statements)

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“…The best ways to design OPMs, sensor arrays, and magnetic shielding (which controls background fields) are not yet settled, and there is relatively little open-source data available from OPM-MEG systems. In this paper, we aimed to evaluate a recently developed triaxial OPM-MEG instrument (Boto et al, 2022; Rea et al, 2022) via quantitative assessment of test-retest reliability for the measurement of human connectomics. We further intended to generate an open-source dataset to allow other researchers to assess OPM-MEG capabilities.…”

Section: Introductionmentioning

confidence: 99%

Test-Retest Reliability of the Human Connectome: An OPM-MEG study

Rier

Michelmann

Ritz

et al. 2022

Preprint

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Magnetoencephalography with optically pumped magnetometers (OPM-MEG) offers a new way to record electrophysiological brain function, with significant advantages over conventional MEG including adaptability to head shape/size, free movement during scanning, better spatial resolution, increased signal, and no reliance on cryogenics. However, OPM-MEG remains in its infancy, with significant questions to be answered regarding optimal system design and robustness. Here, we present an open-source dataset acquired using a newly constructed OPM-MEG system with a triaxial sensor design averaging 168 channels. Using OPM-optimised magnetic shielding and active background-field control, we measure the test-retest reliability of the human connectome. We employ amplitude envelope correlation to measure whole-brain functional connectivity in 10 individuals whilst they watch a 600 s move clip. Our results show high repeatability between experimental runs at the group level, with a correlation coefficient of 0.81 in the theta, 0.93 in alpha and 0.94 in beta frequency ranges. At the individual subject level, we found marked differences between individuals, but high within-subject robustness (correlations of 0.56 ± 0.25, 0.72 ± 0.15 and 0.78 ± 0.13 in theta, alpha and beta respectively). These results compare well to previously reported findings using conventional MEG; they show that OPM-MEG is a viable way to characterise whole brain connectivity and add significant weight to a growing argument that OPMs can overtake cryogenic sensors as the fundamental building block of MEG systems.

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Section: Introductionmentioning

confidence: 99%

Test-Retest Reliability of the Human Connectome: An OPM-MEG study

Rier

Michelmann

Ritz

et al. 2022

Preprint

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“…For three patients the SNRs of IEDs were (slightly) lower in the OPM data than in the SQUID data, but with negligible effect sizes for two of these patients. Recording along two axes with the OPMs could be a contributing factor here, as this results in a slight reduction in sensitivity (∼30% reported by Osborne et al (2018), but less by Rea et al (2022)). A further possible explanation for this finding could be an insufficient coverage by the limited number of OPMs used in this study.…”

Section: Discussionmentioning

confidence: 78%

“…Recording along two axes with the OPMs could be a contributing factor here, as this results in a slight reduction in sensitivity (~30% reported by Osborne et al (2018), but less by Rea et al (2022)). A further possible explanation for this finding could be an insufficient coverage by the limited number of OPMs used in this study.…”

Section: Comparison Between Systemsmentioning

confidence: 81%

“…Moreover, reducing the field gradients in custom-designed MSRs with degaussing coils (Altarev et al, 2015), or by using field-nulling ‘matrix-coils’ that allow for accurate field control in a large volume (Holmes et al, 2021), would reduce the amplitude of movement-related artefacts to begin with. Finally, closed-loop designs can be used to further reduce movement-related artefacts, either at the OPM-level using a feedback signal to drive the on-board coils (requiring tri-axial sensitivity (Rea et al, 2022)), or through the field-nulling coils by ‘real-time’ updating of the coil calibration matrix, which would ensure optimal field cancellation during movements. With such technical developments, the increased SNR of OPMs (Boto et al, 2016; Boto et al, 2017; Iivanainen et al, 2017) could be utilised to its full extent to accurately localise the SOZ non-invasively.…”

Section: Discussionmentioning

confidence: 99%

“…Six, commercially available Gen2.0 OPMs (QuSpin Inc, Louisville, CO, USA; Zero field magnetometer, 2 nd Generation, dual-axis measurement), with sensitivities of 7-13 fT/√Hz and a dynamic range of ±5 nT (Osborne et al, 2018), were used. We recorded simultaneously along both the radial and a tangential axis to increase the number of measurements and to increase the separability of neuronal and noise signals (Brookes et al, 2021; Nurminen et al, 2013; Rea et al, 2022; Tierney et al, 2021a; Tierney et al, 2022), at a cost of a slight reduction in sensitivity (Osborne et al, 2018). The sensors operate in the spin exchange relaxation-free regime, and the (near) zero-field environment is achieved through ‘on-sensor’ electromagnetic coils wrapped around the vapour cell, that can compensate for remnant fields in the magnetically shielded room (MSR) of up to 50 nT.…”

Section: Methodsmentioning

confidence: 99%

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Improved non-invasive detection of ictal and interictal epileptiform activity using Optically Pumped Magnetometers

Hillebrand

Holmes

Sijsma

et al. 2022

Preprint

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Magneto- and Electroencephalography (MEG/EEG) are important techniques for the diagnosis and pre-surgical evaluation of epilepsy. Yet, in current cryogen-based MEG systems the sensors are offset from the scalp, which limits the signal-to-noise ratio (SNR) and thereby the sensitivity to activity from deep structures such as the hippocampus. This effect is amplified in children, for whom adult-sized fixed-helmet systems are typically too big. Moreover, ictal recordings with fixed-helmet systems are problematic because of limited movement tolerance. Optically Pumped Magnetometers (OPMs) can be placed directly on the scalp, thereby improving SNR and consequently the sensitivity to, and localisation accuracy of, epileptiform activity. In addition, recording during seizures becomes feasible with these wearable sensors. We aimed to demonstrate these advantages of OPMs in a clinical population. Three adults with known weak sources of interictal epileptiform discharges (IEDs), along with three children with focal epilepsy and one adult with frequent seizures underwent MEG recordings using a 12-channel OPM-system and a 306-channel cryogen-based whole-head system. Performance of the two systems was compared in terms of IED-rate and SNR. In one patient the OPMs detected IEDs that were not found with the SQUID-system. In one patient the spike yield was higher for the OPM data (9.00 versus 6.76), with negligible difference in SNR compared to the SQUID data (3.85 versus 3.93; U = -2.86, d = -0.14). This was also the case for a patient with a spike yield that was comparable to that for the SQUID data (after accounting for unilateral coverage with the OPMs; SNR 4.47 versus 4.57; U = -3.81, d = -0.14). For one patient the spike yield (11.03 versus 24.50) and SNR (4.39 versus 4.05; U = 9.53, d = -0.36) were both lower for the OPMs. In two patients no IEDs were found with either system. Importantly, the wearability of OPMs enabled the recording of seizure activity in a patient with hyperkinetic movements during the seizure. The observed ictal onset and semiology were in agreement with previous video- and stereo-EEG recordings. Overall, OPM data were very much comparable to those obtained with a cryogenic system: OPMs outperformed SQUIDs for two of the four patients with IEDs, with either a higher spike yield, or an ability to detect IEDs that were not observable in the SQUID data. For three patients the SNRs of IEDs were (slightly) lower in the OPM data than in the SQUID data, but with negligible effect sizes for two of these patients. The relatively cheap technology, in combination with reduced running and maintenance costs, means that OPM-based MEG could be used more widely than current MEG systems, and may become an affordable alternative to scalp EEG, with the potential benefits of increased spatial accuracy, reduced sensitivity to volume conduction/field spread, and increased sensitivity to deep sources. Wearable MEG thus provides an unprecedented opportunity for epilepsy, and given its patient-friendliness, we envisage that it will not only be used for presurgical evaluation of epilepsy patients, but also for diagnosis after a first seizure.

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System and approach to detecting of gastric slow wave and environmental noise suppression based on optically pumped magnetometer

Liang,

Gao,

et al. 2024

Biocybernetics and Biomedical Engineering

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A 90‐channel triaxial magnetoencephalography system using optically pumped magnetometers

Cited by 53 publications

References 76 publications

Test-Retest Reliability of the Human Connectome: An OPM-MEG study

Test-Retest Reliability of the Human Connectome: An OPM-MEG study

Improved non-invasive detection of ictal and interictal epileptiform activity using Optically Pumped Magnetometers

System and approach to detecting of gastric slow wave and environmental noise suppression based on optically pumped magnetometer

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