Print Email Facebook Twitter Correction of Field Inhomogeneities in Low-Field MRI During Image Reconstruction Title Correction of Field Inhomogeneities in Low-Field MRI During Image Reconstruction: Image Distortion Correction Author Liesker, Bas (TU Delft Electrical Engineering, Mathematics and Computer Science) Contributor Remis, R.F. (mentor) Koolstra, Kirsten (mentor) O'Reilly, Thomas (graduation committee) Budko, N.V. (graduation committee) Degree granting institution Delft University of Technology Project Low-Field MRI Date 2021-05-26 Abstract Magnetic resonance imaging (MRI) scanners are a crucial diagnostic tool for radiologists. They are able to render two and threedimensional images of the body without exposure to harmful radiation. MRI systems are, however, costly to build and maintain. This adversely impacts access to these scanners in developing regions. In an effort to combat this problem, a lowfield MRI scanner is being developed. Conventional MRI scanners utilize a superconducting solenoid to generate the main magnetic field. The lowfield scanner, on the other hand, induces the main magnetic field through a Hallbach array of permanent neodymium magnets. While beneficial for production and maintenance costs, as well as portability, the Hallbach array is not able to generate a perfectly homogeneous magnetic field. The inhomogeneities present in the main magnetic field result in distortion of the images when reconstructed using conventional fast Fourier transform (FFT) methods. To counteract this, a reconstruction method that utilizes field information needs to be employed. In this thesis, existing methods to determine and utilize the field information to correct image distortion are explored. From this analysis, it is evident that modelbased (MB) methods are most suitable for reconstruction of data from the lowfield scanner. Current MB methods are only implemented for twodimensional reconstruction. The goal of this thesis is to expand these methods to threedimensional reconstruction. A novel MB method for threedimensional reconstruction is presented. This new method is able to circumvent memory constraints that arise from reconstruction of large data sets. Though the new method requires several hours to reconstruct a 128 × 128 × 30 data set, visual inspection indicates that an accurate result is achieved. Subject MRILow-FieldInhomogeneitiesImageCorrectionModel-Based3DReconstruction To reference this document use: http://resolver.tudelft.nl/uuid:c254244c-4a74-40ef-886b-ad92126bc9f3 Part of collection Student theses Document type master thesis Rights © 2021 Bas Liesker Files PDF Thesis_Bas_Liesker.pdf 16.5 MB Close viewer /islandora/object/uuid:c254244c-4a74-40ef-886b-ad92126bc9f3/datastream/OBJ/view