Software-based Diffusion MR Human Brain Phantom for Evaluating Fiber-tracking Algorithms

Fiber tracking provides insights into the brain white matter network and has become more and more popular in diffusion MR imaging. Hardware or software phantom provides an essential platform to investigate, validate and compare various tractography algorithms towards a "gold standard". Sof...

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Vydáno v:Proceedings of SPIE, the international society for optical engineering Ročník 8669
Hlavní autoři: Shi, Yundi, Roger, Gwendoline, Vachet, Clement, Budin, Francois, Maltbie, Eric, Verde, Audrey, Hoogstoel, Marion, Berger, Jean-Baptiste, Styner, Martin
Médium: Journal Article
Jazyk:angličtina
Vydáno: United States 13.03.2013
Témata:
Validation
Phantom
Atlas
Fiber tracking
Diffusion-weighted MRI
Tractography
ISSN:0277-786X
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Shrnutí:Fiber tracking provides insights into the brain white matter network and has become more and more popular in diffusion MR imaging. Hardware or software phantom provides an essential platform to investigate, validate and compare various tractography algorithms towards a "gold standard". Software phantoms excel due to their flexibility in varying imaging parameters, such as tissue composition, SNR, as well as potential to model various anatomies and pathologies. This paper describes a novel method in generating diffusion MR images with various imaging parameters from realistically appearing, individually varying brain anatomy based on predefined fiber tracts within a high-resolution human brain atlas. Specifically, joint, high resolution DWI and structural MRI brain atlases were constructed with images acquired from 6 healthy subjects (age 22-26) for the DWI data and 56 healthy subject (age 18-59) for the structural MRI data. Full brain fiber tracking was performed with filtered, two-tensor tractography in atlas space. A deformation field based principal component model from the structural MRI as well as unbiased atlas building was then employed to generate synthetic structural brain MR images that are individually varying. Atlas fiber tracts were accordingly warped into each synthetic brain anatomy. Diffusion MR images were finally computed from these warped tracts via a composite hindered and restricted model of diffusion with various imaging parameters for gradient directions, image resolution and SNR. Furthermore, an open-source program was developed to evaluate the fiber tracking results both qualitatively and quantitatively based on various similarity measures.
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ISSN:0277-786X
DOI:10.1117/12.2006113