Peripheral Nerve Magnetoneurography With Optically Pumped Magnetometers

Bu, Yifeng; Prince, Jacob; Mojtahed, Hamed; Kimball, D.; Shah, Vishal; Coleman, Todd P.; Sarkar, Mahasweta; Rao, Ramesh; Huang, Mingxiong; Schwindt, Peter D. D.; Borna, Amir; Lerman, Imanuel

doi:10.3389/fphys.2022.798376

Cited by 11 publications

(4 citation statements)

References 31 publications

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“…Arrays can be designed to target specific brain regions with high sensor density, for example, if high spatial resolution is desired in a specific area (recently published examples include the language network [19], hippocampus [20], and cerebellum [21]). It is also becoming apparent that OPM use is not limited to the brain, with arrays also having been used to measure electrophysiological signals in the muscles [22], peripheral nerves [23], spinal cord [24], retina [25], and the foetus [26]. Another advantage is that, whereas SQUIDs typically measure the magnetic field in one orientation (usually radial to the A participant sits with their head in a static helmet (see inset photo, adapted from [16]), containing an array of field sensors (blue circles).…”

Section: Box 1 Opm Physicsmentioning

confidence: 99%

Magnetoencephalography with optically pumped magnetometers (OPM-MEG): the next generation of functional neuroimaging

Brookes

Leggett

Rea

et al. 2022

Trends in Neurosciences

122

100

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Section: Box 1 Opm Physicsmentioning

confidence: 99%

Magnetoencephalography with optically pumped magnetometers (OPM-MEG): the next generation of functional neuroimaging

Brookes

Leggett

Rea

et al. 2022

Trends in Neurosciences

122

100

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“…The new generation of MMG sensors, such as TMR, do not have a limitation for frequency bandwidth 12 . However, there is a trade-off between the bandwidth and the sensitivity of a magnetic sensor, which means that they cannot be optimized simultaneously, as increasing the bandwidth would reduce the sensitivity of the sensor ( Bu et al, 2022 ).…”

Section: Discussion and Future Perspectivementioning

confidence: 99%

Alignment of magnetic sensing and clinical magnetomyography

et al. 2023

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Neuromuscular diseases are a prevalent cause of prolonged and severe suffering for patients, and with the global population aging, it is increasingly becoming a pressing concern. To assess muscle activity in NMDs, clinicians and researchers typically use electromyography (EMG), which can be either non-invasive using surface EMG, or invasive through needle EMG. Surface EMG signals have a low spatial resolution, and while the needle EMG provides a higher resolution, it can be painful for the patients, with an additional risk of infection. The pain associated with the needle EMG can pose a risk for certain patient groups, such as children. For example, children with spinal muscular atrophy (type of NMD) require regular monitoring of treatment efficacy through needle EMG; however, due to the pain caused by the procedure, clinicians often rely on a clinical assessment rather than needle EMG. Magnetomyography (MMG), the magnetic counterpart of the EMG, measures muscle activity non-invasively using magnetic signals. With super-resolution capabilities, MMG has the potential to improve spatial resolution and, in the meantime, address the limitations of EMG. This article discusses the challenges in developing magnetic sensors for MMG, including sensor design and technology advancements that allow for more specific recordings, targeting of individual motor units, and reduction of magnetic noise. In addition, we cover the motor unit behavior and activation pattern, an overview of magnetic sensing technologies, and evaluations of wearable, non-invasive magnetic sensors for MMG.

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“…Wikswo [155] produced some of the first magnetic field measurements of nerve impulses followed by numerous incremental improvements in application to the human nerve that continue to be ongoing [156][157][158]. Ionic current flow (as measured by conventional surface electrodes) also generates a tiny magnetic field, which can be detected by magnetometers, the most applied of which being superconducting quantum interference device (SQUID) magnetoencephalography (MEG) systems [158] and more recently optically pumped magnetometers [159,160] (OPMs, figure 9). The ability to non-invasively produce high resolution pictures of intra-axonal as well as inward currents in deep nerves (depth-independent) throughout the entire neural pathway, including plexus, roots, spine, and brain would clearly be of significant value [161].…”

Section: Magnetoneurographymentioning

confidence: 99%

A scoping review of current and emerging techniques for evaluation of peripheral nerve health, degeneration, and regeneration: part 1, neurophysiology

et al. 2023

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Peripheral neuroregeneration research and therapeutic options are expanding exponentially. With this expansion comes an increasing need to reliably evaluate and quantify nerve health. Valid and responsive measures that can serve as biomarkers of the nerve status are essential for both clinical and research purposes for diagnosis, longitudinal follow-up, and monitoring the impact of any intervention. Furthermore, such biomarkers can elucidate regeneration mechanisms and open new avenues for research. Without these measures, clinical decision-making falls short, and research becomes more costly, time-consuming, and sometimes infeasible. As a companion to Part 2, which is focused on non-invasive imaging, Part 1 of this two-part scoping review systematically identifies and critically examines many current and emerging neurophysiological techniques that have the potential to evaluate peripheral nerve health, particularly from the perspective of regenerative therapies and research.

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Peripheral Nerve Magnetoneurography With Optically Pumped Magnetometers

Cited by 11 publications

References 31 publications

Magnetoencephalography with optically pumped magnetometers (OPM-MEG): the next generation of functional neuroimaging

Magnetoencephalography with optically pumped magnetometers (OPM-MEG): the next generation of functional neuroimaging

Alignment of magnetic sensing and clinical magnetomyography

A scoping review of current and emerging techniques for evaluation of peripheral nerve health, degeneration, and regeneration: part 1, neurophysiology

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