Multi-Contrast Magnetic Particle Imaging

Magnetic particle imaging is a tracer-based tomographic imaging technique that uses static and oscillating magnetic fields to generate an image contrast from the spatial distribution of magnetic nanoparticles. Recent investigations have shown that multi-contrast MPI is able to generate additional contrasts from different tracer materials or their environments. In this project we investigate tracer properties and properties of the particle environment that influence the tracer relaxation behavior using multi-contrast MPI, such as

To speed up the multi-contrast MPI image reconstruction, we have introduced an accelerated Kaczmarz algorithm. we have also introduced some potential medical and physical applications of multi-contrast MPI, such as 3D tracking of endovascular devices and balloon catheter imaging

Using the Accelerated Kaczmarz for multi-contrast MPI reconstruction speeds up the convergence.

Publications

[56729]
Title: Discriminating nanoparticle core size using multi-contrast MPI.
Written by: C. Shasha, E. Teeman, K. M. Krishnan, P. Szwargulski, T. Knopp, and M. Möddel
in: <em>Physics in Medicine and Biology</em>. (2019).
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DOI: https://doi.org/10.1088/1361-6560/ab0fc9
URL: https://iopscience.iop.org/article/10.1088/1361-6560/ab0fc9
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Note: article, multi-contrast

Abstract: Magnetic particle imaging (MPI) is an imaging modality that detects the response of a distribution of magnetic nanoparticle tracers to static and alternating magnetic fields. There has recently been exploration into multi-contrast MPI, in which the signal from different tracer materials or environments is separately reconstructed, resulting in multi-channel images that could enable temperature or viscosity quantification. In this work, we apply a multi-contrast reconstruction technique to discriminate between nanoparticle tracers of different core sizes. Three nanoparticle types with core diameters of 21.9nm, 25.3nm, and 27.7nm were each imaged at 21 different locations within the scanner field of view. Multi-channel images were reconstructed for each sample and location, with each channel corresponding to one of the three core sizes. For each image, signal weight vectors were calculated, which were then used to classify each image by core size. With a block averaging length of 10000, the median signal-to-noise ratio was 40 or higher for all three sample types, and a correct prediction rate of 96.7% was achieved, indicating that core size can effectively be predicted using signal weight vector classification with close to 100% accuracy while retaining high MPI image quality.