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Main Authors: Zhao, Biqi Rebekah, Chou, Alexander, Peltekov, Robert, Alon, Elad, Liu, Chunlei, Muller, Rikky, Lustig, Michael
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.00143
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author Zhao, Biqi Rebekah
Chou, Alexander
Peltekov, Robert
Alon, Elad
Liu, Chunlei
Muller, Rikky
Lustig, Michael
author_facet Zhao, Biqi Rebekah
Chou, Alexander
Peltekov, Robert
Alon, Elad
Liu, Chunlei
Muller, Rikky
Lustig, Michael
contents Magnetic resonance imaging (MRI) exhibits rich and clinically useful endogenous contrast mechanisms, which can differentiate soft tissues and are sensitive to flow, diffusion, magnetic susceptibility, blood oxygenation level, and more. However, MRI sensitivity is ultimately constrained by Nuclear Magnetic Resonance (NMR) physics, and its spatiotemporal resolution is limited by SNR and spatial encoding. On the other hand, miniaturized implantable sensors offer highly localized physiological information, yet communication and localization can be challenging when multiple implants are present. This paper introduces the MRDust, an active ``contrast agent" that integrates active sensor implants with MRI, enabling the direct encoding of highly localized physiological data into MR images to augment the anatomical images. MRDust employs a micrometer-scale on-chip coil to actively modulate the local magnetic field, enabling MR signal amplitude and phase modulation for digital data transmission. Since MRI inherently captures the anatomical tissue structure, this method has the potential to enable simultaneous data communication, localization, and image registration with multiple implants. This paper presents the underlying physical principles, design tradeoffs, and design methodology for this approach. To validate the concept, a 900 $\times$ 990 $μ$m$^2$ chip was designed using TSMC 28 nm technology, with an on-chip coil measuring 630 $μ$m in diameter. The chip was tested with custom hardware in an MR750W GE3T MRI scanner. Successful voxel amplitude modulation is demonstrated with Spin-Echo Echo-Planar-Imaging (SE-EPI) sequence, achieving a contrast-to-noise ratio (CNR) of 25.58 with a power consumption of 130 $μ$W.
format Preprint
id arxiv_https___arxiv_org_abs_2506_00143
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MRDust: Wireless Implant Data Uplink & Localization via Magnetic Resonance Image Modulation
Zhao, Biqi Rebekah
Chou, Alexander
Peltekov, Robert
Alon, Elad
Liu, Chunlei
Muller, Rikky
Lustig, Michael
Systems and Control
Magnetic resonance imaging (MRI) exhibits rich and clinically useful endogenous contrast mechanisms, which can differentiate soft tissues and are sensitive to flow, diffusion, magnetic susceptibility, blood oxygenation level, and more. However, MRI sensitivity is ultimately constrained by Nuclear Magnetic Resonance (NMR) physics, and its spatiotemporal resolution is limited by SNR and spatial encoding. On the other hand, miniaturized implantable sensors offer highly localized physiological information, yet communication and localization can be challenging when multiple implants are present. This paper introduces the MRDust, an active ``contrast agent" that integrates active sensor implants with MRI, enabling the direct encoding of highly localized physiological data into MR images to augment the anatomical images. MRDust employs a micrometer-scale on-chip coil to actively modulate the local magnetic field, enabling MR signal amplitude and phase modulation for digital data transmission. Since MRI inherently captures the anatomical tissue structure, this method has the potential to enable simultaneous data communication, localization, and image registration with multiple implants. This paper presents the underlying physical principles, design tradeoffs, and design methodology for this approach. To validate the concept, a 900 $\times$ 990 $μ$m$^2$ chip was designed using TSMC 28 nm technology, with an on-chip coil measuring 630 $μ$m in diameter. The chip was tested with custom hardware in an MR750W GE3T MRI scanner. Successful voxel amplitude modulation is demonstrated with Spin-Echo Echo-Planar-Imaging (SE-EPI) sequence, achieving a contrast-to-noise ratio (CNR) of 25.58 with a power consumption of 130 $μ$W.
title MRDust: Wireless Implant Data Uplink & Localization via Magnetic Resonance Image Modulation
topic Systems and Control
url https://arxiv.org/abs/2506.00143