Abstract
Magnetic manipulation is of high interest in terms of drug targeting and minimally invasive surgery. Drugs, bound to magnetic beads can be directed by external magnetic fields towards a specific volume. Devices, as micro surgical tools, video or drug filled capsules can be directed into tissue regions which are difficult to access.
It needs to be considered, how to image and monitor the manipulation process: in-vivo applications need to be imaged with a tomographic and real time imaging technique. Here, Magnetic Particle Imaging (MPI) is a promising method. An MPI scanner features a magnetic drive field for particle excitation. To spatially encode the induced particle signal, a magnetic gradient field is applied. Furthermore, a homogenous magnetic offset field, so called focus field, enlarges the field of view.
The magnetic fields of existing MPI scanners can be also used for magnetic manipulation. First, a magnetic force can be induced by the selection field that points along the field gradient towards the highest field amplitudes. Second, the focus fields can be rotated which induces a circular movement of magnetic material located inside the scanner. Different shapes, materials and sizes of devices and particles are investigated regarding their potential of both magnetic manipulation and imaging inside an MPI scanner.
It needs to be considered, how to image and monitor the manipulation process: in-vivo applications need to be imaged with a tomographic and real time imaging technique. Here, Magnetic Particle Imaging (MPI) is a promising method. An MPI scanner features a magnetic drive field for particle excitation. To spatially encode the induced particle signal, a magnetic gradient field is applied. Furthermore, a homogenous magnetic offset field, so called focus field, enlarges the field of view.
The magnetic fields of existing MPI scanners can be also used for magnetic manipulation. First, a magnetic force can be induced by the selection field that points along the field gradient towards the highest field amplitudes. Second, the focus fields can be rotated which induces a circular movement of magnetic material located inside the scanner. Different shapes, materials and sizes of devices and particles are investigated regarding their potential of both magnetic manipulation and imaging inside an MPI scanner.
Originalsprache | Englisch |
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Titel | Verhandlungen der Deutschen Physikalischen Gesellschaft Würzburg 2018 |
Erscheinungsdatum | 20.03.2018 |
Publikationsstatus | Veröffentlicht - 20.03.2018 |
Veranstaltung | DPG-Frühjahrstagung - Würzburg, Deutschland Dauer: 19.03.2018 → 23.03.2018 |