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Verlagslink DOI: 10.1088/1361-6560/aa5340
Titel: Hybrid system calibration for multidimensional magnetic particle imaging
Sprache: English
Autor/Autorin: Gladiß, Anselm von 
Gräser, Matthias 
Szwargulski, Patryk 
Knopp, Tobias 
Buzug, Thorsten M. 
Schlagwörter: system calibration;magnetic particle imaging;background correction;hybrid system matrix;spatial resolution;signal-to-noise ratio;acquisition time
Erscheinungsdatum: 5-Apr-2017
Verlag: Institute of Physics Publishing (IOP); Institute of Physics and Engineering in Medicine
Quellenangabe: Physics in medicine and biology 9 (62): 3392-3406 (2017)
Zeitschrift oder Schriftenreihe: Physics in medicine and biology 
Zusammenfassung (englisch): Magnetic particle imaging visualizes the spatial distribution of superparamagnetic nanoparticles. Because of its key features of excellent sensitivity, high temporal and spatial resolution and biocompatibility of the tracer material it can be used in multiple medical imaging applications. The common reconstruction technique for Lissajous-type trajectories uses a system matrix that has to be previously acquired in a time-consuming calibration scan, leading to long downtimes of the scanning device. In this work, the system matrix is determined by a hybrid approach. Using the hybrid system matrix for reconstruction, the calibration downtime of the scanning device can be neglected. Furthermore, the signal to noise ratio of the hybrid system matrix is much higher, since the size of the required nanoparticle sample can be chosen independently of the desired voxel size. As the signal to noise ratio influences the reconstruction process, the resulting images have better resolution and are less affected by artefacts. Additionally, a new approach is introduced to address the background signal in image reconstruction. The common technique of subtraction of the background signal is replaced by extending the system matrix with an entry that represents the background. It is shown that this approach reduces artefacts in the reconstructed images.
URI: http://tubdok.tub.tuhh.de/handle/11420/1895
DOI: 10.15480/882.1892
ISSN: 1361-6560
Institut: Biomedizinische Bildgebung E-5 
Dokumenttyp: (wissenschaftlicher) Artikel
Sponsor / Fördernde Einrichtung: DFG, grant number BU 1436/10-1, DFG grant numbers KN 1108/2-1, AD 125/5-1
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