Thomas Hackländer1, Heinrich Mertens. 1. HELIOS Klinikum Wuppertal, Hospital of the University Witten/Herdecke, Department of Radiology, Heusnerstrasse 40, 42283 Wuppertal, Germany. thacklaender@wuppertal.helios-kliniken.de
Abstract
RATIONALE AND OBJECTIVE: The aim of this project was to simulate the features and functions of a clinical or real-world MR scanner on a personal computer by means of a computer program. The users should be able to change all relevant settings of the virtual scanner and adapt them to the expected pathology. MATERIALS AND METHODS: The algorithms of the simulation are based on parameter images of the three physical basic properties T1, T2, and proton density. From this, the synthetic images are calculated pixel by pixel on the basis of the well-known formulas of the pulse sequences chosen and modified by the user. The graphical user interface is oriented to a real-world MR scanner. The software is programmed in pure Java and is freely available under the GPL license. RESULTS: Besides spin echo pulse sequence, 6 other pulse sequence classes are implemented. Parameters like repetition time and echo time can be adjusted. The choice of parameters like matrix size, slice-thickness, and number of acquisitions has an impact on the signal-to-noise ratio of the images. In a first step, the simulation calculates the signal intensity in k-space. Wraparound and motion artifacts are simulated by modifying the data of k-space. In a last step, a 2D-Fourier transform of k-space data is performed. As the image calculation takes only a few seconds, an interactive manner of working is possible. CONCLUSION: The simulation has been used in the education of medical students and interns for more than 1 year and has gained widespread acceptance.
RATIONALE AND OBJECTIVE: The aim of this project was to simulate the features and functions of a clinical or real-world MR scanner on a personal computer by means of a computer program. The users should be able to change all relevant settings of the virtual scanner and adapt them to the expected pathology. MATERIALS AND METHODS: The algorithms of the simulation are based on parameter images of the three physical basic properties T1, T2, and proton density. From this, the synthetic images are calculated pixel by pixel on the basis of the well-known formulas of the pulse sequences chosen and modified by the user. The graphical user interface is oriented to a real-world MR scanner. The software is programmed in pure Java and is freely available under the GPL license. RESULTS: Besides spin echo pulse sequence, 6 other pulse sequence classes are implemented. Parameters like repetition time and echo time can be adjusted. The choice of parameters like matrix size, slice-thickness, and number of acquisitions has an impact on the signal-to-noise ratio of the images. In a first step, the simulation calculates the signal intensity in k-space. Wraparound and motion artifacts are simulated by modifying the data of k-space. In a last step, a 2D-Fourier transform of k-space data is performed. As the image calculation takes only a few seconds, an interactive manner of working is possible. CONCLUSION: The simulation has been used in the education of medical students and interns for more than 1 year and has gained widespread acceptance.
Authors: Daniel Treceño-Fernández; Juan Calabia-Del-Campo; Miguel L Bote-Lorenzo; Eduardo Gómez Sánchez; Rodrigo de Luis-García; Carlos Alberola-López Journal: J Med Syst Date: 2019-12-02 Impact factor: 4.460
Authors: Harm A Nieuwstadt; Zaid A M Kassar; Aad van der Lugt; Marcel Breeuwer; Anton F W van der Steen; Jolanda J Wentzel; Frank J H Gijsen Journal: PLoS One Date: 2015-04-09 Impact factor: 3.240
Authors: Fang Liu; Julia V Velikina; Walter F Block; Richard Kijowski; Alexey A Samsonov Journal: IEEE Trans Med Imaging Date: 2016-10-25 Impact factor: 10.048