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Optically pumped magnetometers reveal fasciculations non-invasively

Justus Marquetand, Thomas Middelmann, Juergen Dax, Sangyeob Baek, Davide Sometti, Alexander Grimm, Holger Lerche, Pascal Martin, Cornelius Kronlage, Markus Siegel, Christoph Braun, Philip J. Broser

2021Clinical Neurophysiology37 citationsDOIOpen Access PDF

Abstract

OBJECTIVE: This proof-of-principle-study evaluated the extent to which spontaneous activity (SA) of the muscle can be detected via non-invasive magnetomyography (MMG) with optically pumped magnetometers (OPM). METHODS: Five patients, who together exhibited all forms of SA (fibrillations, positive sharp waves, fasciculations, myotonic discharges, complex-repetitive discharges) with conventional needle electromyography (EMG), were studied by OPM-MMG and simultaneous surface EMG (sEMG) while at rest, during light muscle activation, and when a muscle stretch reflex was elicited. Three healthy subjects were measured as controls. SA was considered apparent in the OPM-MMG if a signal could be visually detected that corresponded in shape and frequency to the SA in the respective needle EMG. RESULTS: SA in the context of fasciculations could be detected in 2 of 5 patients by simultaneous OPM-MMG/sEMG. Other forms of SA could not be detected at rest, during light muscle activation, or after provocation of a muscle stretch reflex. CONCLUSIONS: Results show that fasciculations could be detected non-invasively via a new method (OPM). SIGNIFICANCE: We show that other forms of SA are not detectable with current OPM and propose necessary technical solutions to overcome this circumstance. Our results motivate to pursue OPM-MMG as a new clinical neurophysiological diagnostic.

Topics & Concepts

FasciculationMagnetometerMedicineCardiologyPhysicsAnesthesiaMagnetic fieldQuantum mechanicsAtomic and Subatomic Physics ResearchMagnetic Field Sensors TechniquesGeophysics and Sensor Technology