Trajectory analysis for magnetic particle imaging

T. Knopp; S. Biederer; T. Sattel; J. Weizenecker; B. Gleich; J. Borgert; T. M. Buzug

doi:10.1088/0031-9155/54/2/014

Trajectory analysis for magnetic particle imaging

T. Knopp^*, S. Biederer, T. Sattel, J. Weizenecker, B. Gleich, J. Borgert, T. M. Buzug

^*Korrespondierende/r Autor/-in für diese Arbeit

Institut für Medizintechnik

Philips Research Laboratories

102 Zitate (Scopus)

Abstract

Recently a new imaging technique called magnetic particle imaging was proposed. The method uses the nonlinear response of magnetic nanoparticles when a time varying magnetic field is applied. Spatial encoding is achieved by moving a field-free point through an object of interest while the field strength in the vicinity of the point is high. A resolution in the submillimeter range is provided even for fast data acquisition sequences. In this paper, a simulation study is performed on different trajectories moving the field-free point through the field of view. The purpose is to provide mandatory information for the design of a magnetic particle imaging scanner. Trajectories are compared with respect to density, speed and image quality when applied in data acquisition. Since simulation of the involved physics is a time demanding task, moreover, an efficient implementation is presented utilizing caching techniques.

Originalsprache	Englisch
Zeitschrift	Physics in Medicine and Biology
Jahrgang	54
Ausgabenummer	2
Seiten (von - bis)	385-397
Seitenumfang	13
ISSN	0031-9155
DOIs	https://doi.org/10.1088/0031-9155/54/2/014
Publikationsstatus	Veröffentlicht - 21.01.2009

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AU - Knopp, T.

AU - Biederer, S.

AU - Sattel, T.

AU - Weizenecker, J.

AU - Gleich, B.

AU - Borgert, J.

AU - Buzug, T. M.

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N2 - Recently a new imaging technique called magnetic particle imaging was proposed. The method uses the nonlinear response of magnetic nanoparticles when a time varying magnetic field is applied. Spatial encoding is achieved by moving a field-free point through an object of interest while the field strength in the vicinity of the point is high. A resolution in the submillimeter range is provided even for fast data acquisition sequences. In this paper, a simulation study is performed on different trajectories moving the field-free point through the field of view. The purpose is to provide mandatory information for the design of a magnetic particle imaging scanner. Trajectories are compared with respect to density, speed and image quality when applied in data acquisition. Since simulation of the involved physics is a time demanding task, moreover, an efficient implementation is presented utilizing caching techniques.

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Trajectory analysis for magnetic particle imaging

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