Litcius/Paper detail

Suppression of Motion Artifacts Caused by Temporally Recurring Tracer Distributions in Multi-Patch Magnetic Particle Imaging

Nadine Gdaniec, Marija Boberg, Martin Möddel, Patryk Szwargulski, Tobias Knopp

2020IEEE Transactions on Medical Imaging18 citationsDOIOpen Access PDF

Abstract

Magnetic particle imaging is a tracer based imaging technique to determine the spatial distribution of superparamagnetic iron oxide nanoparticles with a high spatial and temporal resolution. Due to physiological constraints, the imaging volume is restricted in size and larger volumes are covered by shifting object and imaging volume relative to each other. This results in reduced temporal resolution, which can lead to motion artifacts when imaging dynamic tracer distributions. A common source of such dynamic distributions are cardiac and respiratory motion in in-vivo experiments, which are in good approximation periodic. We present a raw data processing technique that combines data snippets into virtual frames corresponding to a specific state of the dynamic motion. The technique is evaluated on the basis of measurement data obtained from a rotational phantom at two different rotational frequencies. These frequencies are determined from the raw data without reconstruction and without an additional navigator signal. The reconstructed images give reasonable representations of the rotational phantom frozen in several different states of motion while motion artifacts are suppressed.

Topics & Concepts

Imaging phantomTemporal resolutionMagnetic particle imagingImage resolutionIterative reconstructionRotation around a fixed axisComputer visionTRACERDynamic imagingSIGNAL (programming language)PhysicsArtificial intelligenceNuclear magnetic resonanceComputer scienceMagnetic nanoparticlesOpticsImage processingDigital image processingImage (mathematics)NanoparticleProgramming languageQuantum mechanicsNuclear physicsClassical mechanicsCharacterization and Applications of Magnetic NanoparticlesGeomagnetism and Paleomagnetism StudiesMicrofluidic and Bio-sensing Technologies