Magnetic particle imaging in vascular medicine

Magnetic particle imaging (MPI) is a new medical imaging technique that enables three-dimensional real-time imaging of a magnetic tracer material. Although it is not yet in clinical use, it is highly promising, especially for vascular and interventional imaging. The advantages of MPI are that no ion...

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Published in:Innovative surgical sciences 2018-10, Vol.3 (3), p.179-192
Main Authors: Bakenecker, Anna C., Ahlborg, Mandy, Debbeler, Christina, Kaethner, Christian, Buzug, Thorsten M., Lüdtke-Buzug, Kerstin
Format: Article
Language:English
Subjects:
cardiovascular intervention
functional imaging
image reconstruction
magnetic nanoparticles
medical imaging
MPI scanner
quantitative imaging
real-time imaging
Review
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cites cdi_FETCH-LOGICAL-c481t-19ac92a13ccc7899ea2386c0f641144781fb5f37e1d677973e7669294949bc773
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container_title Innovative surgical sciences
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creator Bakenecker, Anna C.
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Kaethner, Christian
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description Magnetic particle imaging (MPI) is a new medical imaging technique that enables three-dimensional real-time imaging of a magnetic tracer material. Although it is not yet in clinical use, it is highly promising, especially for vascular and interventional imaging. The advantages of MPI are that no ionizing radiation is necessary, its high sensitivity enables the detection of very small amounts of the tracer material, and its high temporal resolution enables real-time imaging, which makes MPI suitable as an interventional imaging technique. As MPI is a tracer-based imaging technique, functional imaging is possible by attaching specific molecules to the tracer material. In the first part of this article, the basic principle of MPI will be explained and a short overview of the principles of the generation and spatial encoding of the tracer signal will be given. After this, the used tracer materials as well as their behavior in MPI will be introduced. A subsequent presentation of selected scanner topologies will show the current state of research and the limitations researchers are facing on the way from preclinical toward human-sized scanners. Furthermore, it will be briefly shown how to reconstruct an image from the tracer materials’ signal. In the last part, a variety of possible future clinical applications will be presented with an emphasis on vascular imaging, such as the use of MPI during cardiovascular interventions by visualizing the instruments. Investigations will be discussed, which show the feasibility to quantify the degree of stenosis and diagnose strokes and traumatic brain injuries as well as cerebral or gastrointestinal bleeding with MPI. As MPI is not only suitable for vascular medicine but also offers a broad range of other possible applications, a selection of those will be briefly presented at the end of the article.
doi_str_mv 10.1515/iss-2018-2026
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source PubMed Central; Walter De Gruyter: Open Access Journals
subjects cardiovascular intervention
functional imaging
image reconstruction
magnetic nanoparticles
medical imaging
MPI scanner
quantitative imaging
real-time imaging
Review
title Magnetic particle imaging in vascular medicine
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