Generalized MPI Multi-Patch Reconstruction Using Clusters of Similar System Matrices

The tomographic imaging method magnetic particle imaging (MPI) requires a multi-patch approach for capturing large field of views. This approach consists of a continuous or stepwise spatial shift of a small sub-volume of only few cubic centimeters size, which is scanned using one or multiple excitation fields in the kHz range. Under the assumption of ideal magnetic fields, the MPI system matrix is shift invariant and in turn a single matrix suffices for image reconstruction significantly reducing the calibration time and reconstruction effort. For large field imperfections, however, the method can lead to severe image artifacts. In the present work we generalize the efficient multi-patch reconstruction to work under non-ideal field conditions, where shift invariance holds only approximately for small shifts of the sub-volume. Patches are clustered based on a magnetic-field-based metric such that in each cluster the shift invariance holds in good approximation. The total number of clusters is the main parameter of our method and allows to trade off calibration time and image artifacts. The magnetic-field-based metric allows to perform the clustering without prior knowledge of the system matrices. The developed reconstruction algorithm is evaluated on a multi-patch measurement sequence with 15 patches, where efficient multi-patch reconstruction with a single calibration measurement leads to strong image artifacts. Analysis reveals that calibration measurements can be decreased from 15 to 11 with no visible image artifacts. A further reduction to 9 is possible with only slight degradation in image quality.

[1]  Jürgen Rahmer,et al.  Fast MPI Demonstrator with Enlarged Field of View , 2010 .

[2]  T Knopp,et al.  Joint reconstruction of non-overlapping magnetic particle imaging focus-field data , 2015, Physics in medicine and biology.

[3]  Jörn Borgert,et al.  Magnetic Particle Imaging (MPI): Experimental Quantification of Vascular Stenosis Using Stationary Stenosis Phantoms , 2017, PloS one.

[4]  Bernhard Gleich,et al.  MPI Safety in the View of MRI Safety Standards , 2015, IEEE Transactions on Magnetics.

[5]  W H Kullmann,et al.  First in vivo traveling wave magnetic particle imaging of a beating mouse heart , 2016, Physics in medicine and biology.

[6]  B Gleich,et al.  Weighted iterative reconstruction for magnetic particle imaging , 2010, Physics in medicine and biology.

[7]  Jochen Franke,et al.  Magnetic Particle Imaging: A Resovist based Marking Technology for Guide Wires and Catheters for Vascular Interventions. , 2016, IEEE transactions on medical imaging.

[8]  N. J. A. Sloane,et al.  McLaren’s improved snub cube and other new spherical designs in three dimensions , 1996, Discret. Comput. Geom..

[9]  Tobias Knopp,et al.  Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics , 2016, PloS one.

[10]  Tobias Knopp,et al.  Magnetic particle imaging: from proof of principle to preclinical applications , 2017, Physics in medicine and biology.

[11]  Tobias Knopp,et al.  Efficient Joint Image Reconstruction of Multi-Patch Data Reusing a Single System Matrix in Magnetic Particle Imaging , 2019, IEEE Transactions on Medical Imaging.

[12]  Matthias Graeser,et al.  Magnetic Particle Imaging for Real-Time Perfusion Imaging in Acute Stroke. , 2017, ACS nano.

[13]  Bernhard Gleich,et al.  Signal encoding in magnetic particle imaging: properties of the system function , 2009, BMC Medical Imaging.

[14]  Thorsten M. Buzug,et al.  Artifact free reconstruction with the system matrix approach by overscanning the field-free-point trajectory in magnetic particle imaging , 2016, Physics in medicine and biology.

[15]  T Knopp,et al.  Using data redundancy gained by patch overlaps to reduce truncation artifacts in magnetic particle imaging , 2016, Physics in medicine and biology.

[16]  Matthias Graeser,et al.  Moving table magnetic particle imaging: a stepwise approach preserving high spatio-temporal resolution , 2018, Journal of medical imaging.

[17]  Zhou Wang,et al.  On the Mathematical Properties of the Structural Similarity Index , 2012, IEEE Transactions on Image Processing.

[18]  Olaf Dössel,et al.  CALCULATION AND EVALUATION OF CURRENT DENSITIES AND THERMAL HEATING IN THE BODY DURING MPI , 2010 .

[19]  Tobias Knopp,et al.  Sensitivity Enhancement in Magnetic Particle Imaging by Background Subtraction , 2016, IEEE Transactions on Medical Imaging.

[20]  Patrick W. Goodwill,et al.  Magnetostimulation Limits in Magnetic Particle Imaging , 2013, IEEE Transactions on Medical Imaging.

[21]  C. Beentjes,et al.  QUADRATURE ON A SPHERICAL SURFACE , 2016 .

[22]  Tobias Knopp,et al.  MPIReco.jl: Julia Package for Image Reconstruction in MPI , 2019 .

[23]  M. Grüttner,et al.  System matrices for field of view patches in magnetic particle imaging , 2013, Medical Imaging.

[24]  Tobias Knopp,et al.  Edge Preserving and Noise Reducing Reconstruction for Magnetic Particle Imaging , 2017, IEEE Transactions on Medical Imaging.

[25]  Tobias Knopp,et al.  Fast multiresolution data acquisition for magnetic particle imaging using adaptive feature detection , 2017, Medical physics.