Variational Model-Based Reconstruction Techniques for Multi-Patch Data in Magnetic Particle Imaging
Magnetic Particle Imaging is an emerging imaging modality through which it is possible to detect tracers containing superparamagnetic nanoparticles. The exposure of the particles to dynamic magnetic fields generates a non-linear response that is used to locate the particles and produce an image of their distribution. The bounding box that can be covered by a single scan curve depends on the strength of the gradients of the magnetic fields applied, which is limited due to the risk of causing peripheral nerve stimulation (PNS) in the patients. To address this issue, multiple scans are performed by practitioners. The scan data must be merged together to produce reconstructions of larger regions of interest. In this paper we propose a mathematical framework which generalizes the current multi-patch scanning by utilizing transformations. We show the flexibility of this framework in a variety of different scanning approaches. Moreover, we describe an iterative reconstruction algorithm, show its convergence to a minimizer and perform numerical experiments on simulated data.
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