2005
DOI: 10.1016/j.media.2005.05.008
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White matter tractography by anisotropic wavefront evolution and diffusion tensor imaging

Abstract: Determination of axonal pathways provides an invaluable means to study the connectivity of the human brain and its functional network. Diffusion tensor imaging (DTI) is unique in its ability to capture the restricted diffusion of water molecules which can be used to infer the directionality of tissue components. In this paper, we introduce a white matter tractography method based on anisotropic wavefront propagation in diffusion tensor images. A front propagates in the white matter with a speed profile governe… Show more

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Cited by 66 publications
(77 citation statements)
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“…The extraction of fibers can be done, for instance, by estimating diffusion tensor images and then using streamline tractography (Basser et al, 2000;Fillard et al, 2007a;Malcolm et al, 2010), with possible uncertainty regions (Jackowski et al, 2005;Staempfli et al, 2006) or by using higher order orientation distribution functions Kumar et al, 2009). These algorithms return curves which give an estimation of the location and the orientation of the underlying neural fibers, which are compatible with the measures of diffusivity.…”
Section: Analysis Of Images Versus Analysis Of Anatomical Structuresmentioning
confidence: 99%
“…The extraction of fibers can be done, for instance, by estimating diffusion tensor images and then using streamline tractography (Basser et al, 2000;Fillard et al, 2007a;Malcolm et al, 2010), with possible uncertainty regions (Jackowski et al, 2005;Staempfli et al, 2006) or by using higher order orientation distribution functions Kumar et al, 2009). These algorithms return curves which give an estimation of the location and the orientation of the underlying neural fibers, which are compatible with the measures of diffusivity.…”
Section: Analysis Of Images Versus Analysis Of Anatomical Structuresmentioning
confidence: 99%
“…5,18 The speed of the "wavefront" toward all directions is determined by the colinearity of the principal eigenvectors in the neighboring voxels, following which the direction of fiber tracking in a region-growing manner is assigned as the one with maximum propagation speed. 19 In more advanced fast-marching algorithms, the propagation speed can also be modified on the basis of the magnitude of the eigenvalues rather than on the directions of eigenvectors alone. 20 Other variations capable of resolving crossing fibers have also been proposed.…”
Section: Fast-marching Algorithmsmentioning
confidence: 99%
“…These global approaches are less sensitive to noise. Front propagation techniques (8)(9)(10)(11) identify the best paths from a seed to all other voxels by evolving a surface from this seed. The surface front evolves faster along the fiber direction estimates of the underlying tissue.…”
mentioning
confidence: 99%