Ab Initio Physics Considerations in The Design of Wireless and Non-invasive Neural Recording Systems Using MagnetoElectric Nanoparticles

Ab Initio Physics Considerations in The Design of Wireless and Non-invasive Neural Recording Systems Using MagnetoElectric Nanoparticles

MagnetoElectric NanoParticles (MENPs) provide a way to wirelessly and non-invasively record local neural activity deep in the brain. When administered into the brain, MENPs serve as auxiliary 3D sources, thus offering a solution to the fundamental problem of inverse mathematics that has stifled the...

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Bibliographic Details
Published in:IEEE transactions on magnetics Vol. 59; no. 10; p. 1
Main Authors: Zhang, Elric, Liang, Ping, Yildirim, Yagmur Akin, Chen, Shawnus, Abdel-Mottaleb, Mostafa, Shotbolt, Max, Ramezani, Zeinab, Tian, Jieyuan, Andre, Victoria, Khizroev, Sakhrat
Format: Journal Article
Language:English
Published: New York IEEE 01-10-2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
BMI
Brain
brain-machine interface
Electric fields
Ions
Magnetism
Magnetization
Magnetoelectric effects
Magnetoelectric nanoparticles
Magnetoencephalography
Magnetometers
MENPs
Nanoparticles
Neural activity
neural recording
Recording
Spatial resolution
wireless BMI
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Summary:MagnetoElectric NanoParticles (MENPs) provide a way to wirelessly and non-invasively record local neural activity deep in the brain. When administered into the brain, MENPs serve as auxiliary 3D sources, thus offering a solution to the fundamental problem of inverse mathematics that has stifled the advancement in the field of wireless neural recording from its inception. Owing to the magnetoelectric effect, the MENPs' magnetization is modulated by electric fields due to local neural activity. In turn, this modulated magnetization can be detected via modern magnetometers such as optical pumped magnetometers (OPMs) and nitrogen-vacancy (NV) center devices, already impacting the state of magnetoencephalography (MEG). This basic physics study discusses an aspect which has not been explored to date. There is a strong dependence of the MENPs-based recording on the specific location of the nanoparticles with respect to the neuronal microstructure. This analysis shows that one of the key conditions to enable the MENPs-based recording with a sub-10 -3 -cm 3 spatial resolution in real time would be to ensure the nanoparticles are located specifically on the membrane, where the neural-firing-caused electric field reaches its maximum value. One potential implementation of this high-resolution recording concept would be to integrate MENPs with the recently emerged Magnetic Particle Imaging (MPI).
ISSN:0018-9464
1941-0069
DOI:10.1109/TMAG.2023.3300791