2022 29th IEEE International Conference on Electronics, Circuits and Systems (ICECS) 2022
DOI: 10.1109/icecs202256217.2022.9971020
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Investigating the Volume Conduction Effect in MMG and EMG during Action Potential Recording

Abstract: The study and measurement of the magnetic field from the skeletal muscle is called Magnetomyography (MMG). These magnetic fields are produced by the same ion currents which give rise to the electrical signals that are recorded with electromyography (EMG). Layers between the muscle and skin surface, known as volume conduction, play a critical role during the measurement. This paper presents the volume conduction effect on the electrical and magnetic signals with the finitedifference time-domain simulations usin… Show more

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Cited by 5 publications
(4 citation statements)
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“…We have demonstrated the similarities of MMG to sEMG and highlighted some differences which may allow for better localization using MMG compared to sEMG. Though advantages in localization have been shown in models (Arekhloo et al, 2022;Klotz et al, 2022Klotz et al, , 2023, there has yet to be empirical evidence. Magnetic sensing of the brain (magnetoencephalography (MEG)) has been demonstrated to provide higher localization accuracy compared to electrical sensing (electroencephalography (EEG)) in both a phantom as well as an implanted dipole in humans (Cohen et al, 1990;Cohen & Cuffin, 1991;Leahy et al, 1998), but the results cannot be extended to muscle sensing.…”
Section: Future Directionsmentioning
confidence: 99%
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“…We have demonstrated the similarities of MMG to sEMG and highlighted some differences which may allow for better localization using MMG compared to sEMG. Though advantages in localization have been shown in models (Arekhloo et al, 2022;Klotz et al, 2022Klotz et al, , 2023, there has yet to be empirical evidence. Magnetic sensing of the brain (magnetoencephalography (MEG)) has been demonstrated to provide higher localization accuracy compared to electrical sensing (electroencephalography (EEG)) in both a phantom as well as an implanted dipole in humans (Cohen et al, 1990;Cohen & Cuffin, 1991;Leahy et al, 1998), but the results cannot be extended to muscle sensing.…”
Section: Future Directionsmentioning
confidence: 99%
“…Though the origin of both modalities is the currents traveling through muscle fibers, there are notable differences between how they propagate. sEMG signals are warped by the conductive properties of the signal path -tissue, skin, and the impedance at the sensor interface -whereas the body is permeable to magnetic fields leaving MMG signals unaffected (Arekhloo et al, 2022;Hansen et al, 2010). This distortion introduced to sEMG is highly nonlinear and depends heavily on the subject and day-to-day environmental conditions, introducing difficulties in generalization and scaling with sEMG.…”
Section: Introductionmentioning
confidence: 99%
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“…However, there are two key drivers in employing magnetic sensors rather than electrical sensors for detecting muscle activities. First, unlike electrical signals, magnetic signals have the advantage that their signal strength is minimally affected by the surrounding tissues like skin and subcutaneous fat, as the body’s tissues are effectively transparent to magnetic fields ( Arekhloo et al, 2022 ). Consequently, magnetic signals can be coupled to the electrical current flowing in the muscle fiber and offer significantly higher spatial resolution (~mm).…”
Section: Introductionmentioning
confidence: 99%