[www] [BibTex]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.

[www]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.

[www] [BibTex]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.

[www]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.

[www]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.

[www] [BibTex]

Note: inproceedings, Paper ID: 867219

Abstract: {Magnetic Particle Imaging} ({MPI}) has been presented by Gleich and Weizenecker in 2005. Since then, a number of innovations have been introduced by many di erent research groups. In 2009, for instance, Sattel et al. presented a novel single-sided {MPI} scanner geometry. The major advantage of this particular scanner geometry is the unlimited measurement eld. For the imaging process in {MPI}, super-paramagnetic iron oxide nanoparticles ({SPIONs}) are applied as tracer material. The tracer is excited by sinusoidally varying magnetic elds. In this contribution, simulated magnetic elds were evaluated based on the measured eld distribution of a single-sided scanner realization. It is of particular importance to know the quality of the gradient elds, since image resolution in {MPI} is directly linked to the gradient strength.