The applications of magnetic particle imaging: From cell to body

Xiao Han; Yang Li; Weifeng Liu; Xiaojun Chen; Zeyu Song; Xiaolin Wang; Yulin Deng; Xiaoying Tang; Zhenqi Jiang

doi:10.3390/diagnostics10100800

The applications of magnetic particle imaging: From cell to body

Xiao Han, Yang Li, Weifeng Liu, Xiaojun Chen, Zeyu Song, Xiaolin Wang, Yulin Deng, Xiaoying Tang, Zhenqi Jiang^*

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Contribution to journal › Review article › peer-review

26 Citations (Scopus)

Abstract

Magnetic particle imaging (MPI) is a cutting-edge imaging technique that is attracting increasing attention. This novel technique collects signals from superparamagnetic nanoparticles as its imaging tracer. It has characteristics such as linear quantitativity, positive contrast, unlimited penetration, no radiation, and no background signal from surrounding tissue. These characteristics enable various medical applications. In this paper, we first introduce the development and imaging principles of MPI. Then, we discuss the current major applications of MPI by dividing them into four categories: cell tracking, blood pool imaging, tumor imaging, and visualized magnetic hyperthermia. Even though research on MPI is still in its infancy, we hope this discussion will promote interest in the applications of MPI and encourage the design of tracers tailored for MPI.

Original language	English
Article number	0800
Journal	Diagnostics
Volume	10
Issue number	10
DOIs	https://doi.org/10.3390/diagnostics10100800
Publication status	Published - 9 Oct 2020

Keywords

Cell tracking
Hyperthermia
Imaging tracer
Magnetic particle imaging
Molecular imaging
Nanoparticles
Tumor imaging

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10.3390/diagnostics10100800

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title = "The applications of magnetic particle imaging: From cell to body",

abstract = "Magnetic particle imaging (MPI) is a cutting-edge imaging technique that is attracting increasing attention. This novel technique collects signals from superparamagnetic nanoparticles as its imaging tracer. It has characteristics such as linear quantitativity, positive contrast, unlimited penetration, no radiation, and no background signal from surrounding tissue. These characteristics enable various medical applications. In this paper, we first introduce the development and imaging principles of MPI. Then, we discuss the current major applications of MPI by dividing them into four categories: cell tracking, blood pool imaging, tumor imaging, and visualized magnetic hyperthermia. Even though research on MPI is still in its infancy, we hope this discussion will promote interest in the applications of MPI and encourage the design of tracers tailored for MPI.",

keywords = "Cell tracking, Hyperthermia, Imaging tracer, Magnetic particle imaging, Molecular imaging, Nanoparticles, Tumor imaging",

author = "Xiao Han and Yang Li and Weifeng Liu and Xiaojun Chen and Zeyu Song and Xiaolin Wang and Yulin Deng and Xiaoying Tang and Zhenqi Jiang",

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doi = "10.3390/diagnostics10100800",

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T1 - The applications of magnetic particle imaging

T2 - From cell to body

AU - Han, Xiao

AU - Li, Yang

AU - Liu, Weifeng

AU - Chen, Xiaojun

AU - Song, Zeyu

AU - Wang, Xiaolin

AU - Deng, Yulin

AU - Tang, Xiaoying

AU - Jiang, Zhenqi

PY - 2020/10/9

Y1 - 2020/10/9

N2 - Magnetic particle imaging (MPI) is a cutting-edge imaging technique that is attracting increasing attention. This novel technique collects signals from superparamagnetic nanoparticles as its imaging tracer. It has characteristics such as linear quantitativity, positive contrast, unlimited penetration, no radiation, and no background signal from surrounding tissue. These characteristics enable various medical applications. In this paper, we first introduce the development and imaging principles of MPI. Then, we discuss the current major applications of MPI by dividing them into four categories: cell tracking, blood pool imaging, tumor imaging, and visualized magnetic hyperthermia. Even though research on MPI is still in its infancy, we hope this discussion will promote interest in the applications of MPI and encourage the design of tracers tailored for MPI.

AB - Magnetic particle imaging (MPI) is a cutting-edge imaging technique that is attracting increasing attention. This novel technique collects signals from superparamagnetic nanoparticles as its imaging tracer. It has characteristics such as linear quantitativity, positive contrast, unlimited penetration, no radiation, and no background signal from surrounding tissue. These characteristics enable various medical applications. In this paper, we first introduce the development and imaging principles of MPI. Then, we discuss the current major applications of MPI by dividing them into four categories: cell tracking, blood pool imaging, tumor imaging, and visualized magnetic hyperthermia. Even though research on MPI is still in its infancy, we hope this discussion will promote interest in the applications of MPI and encourage the design of tracers tailored for MPI.

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KW - Hyperthermia

KW - Imaging tracer

KW - Magnetic particle imaging

KW - Molecular imaging

KW - Nanoparticles

KW - Tumor imaging

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JF - Diagnostics

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The applications of magnetic particle imaging: From cell to body

Abstract

Keywords

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