[FSL] [TitleIndex] [WordIndex

Contents

  1. Introduction
  2. User Guide

Research Overview

POSSUM (Physics-Oriented Simulated Scanner for Understanding MRI) is a software tool that produces realistic simulated MRI and FMRI images or time series. POSSUM is part of FSL (FMRIB's Software Library). POSSUM has an easy-to-use graphical user interface (GUI) and its component programs can also be run from the command line. POSSUM includes tools for the pulse sequence generation, signal generation, noise addition and image reconstruction.

POSSUM requires a gradient echo pulse sequence, a segmented object with known tissue parameters, and (optionally) a motion sequence. The way the Bloch equations are solved, by tracking and updating the magnetisation vector through time for every object voxel, allows the changes that occur during the acquisition of one TR to be modelled and then carried through to the acquisition of the next TR, making it possible to simulate spin history effects, motion during the readout periods and interactions that these have with Bo inhomogeneities.

The simulator has the capability to turn on or off various subject- and scanner- related effects, which is not possible in real scanning and therefore has a wide range of applications. These applications include the simulation and removal of various artifacts, both in MRI and FMRI. Furthermore, by generating the "ground truth", the FMRI simulator can be used for evaluation and validation of software tools for FMRI analysis methods (e.g. motion correction, registration, statistical analysis of images, etc.).

If you use POSSUM in your research, please make sure that you reference at least the first of the articles listed below, and ideally the complete list.

  • I Drobnjak, G Pell and M Jenkinson. Simulating the effects of time-varying magnetic fields with a realistic simulated scanner. Magnetic Resonance in Medicine, 28(7), 1014-21, 2010.
  • I Drobnjak, D Gavaghan, E Süli, J Pitt-Francis and M Jenkinson. Development of an FMRI Simulator for Modelling Realistic Rigid-Body Motion Artifacts. Magnetic Resonance in Medicine, 56(2), 364-380, 2006.


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2012-09-05 11:30