TY - GEN
T1 - Probabilistic Tractography for Complex Fiber Orientations with Automatic Model Selection
T2 - MICCAI Workshop on Computational Diffusion MRI, CDMRI 2017
AU - Versteeg, Edwin
AU - Vos, Frans M.
AU - Kwakkel, Gert
AU - van der Helm, Frans C.T.
AU - Arkesteijn, Joor A.M.
AU - Filatova, Olena
PY - 2018/1/1
Y1 - 2018/1/1
N2 - Fiber tractography aims to reconstruct white matter (WM) connections in the brain. Challenges in these reconstructions include estimation of the fiber orientations in regions with multiple fiber populations, and the uncertainty in the fiber orientations as a result of noise. In this work, we use a range of multi-tensor models to cope with crossing fibers. The uncertainty in fiber orientation is captured using the Cramér-Rao lower bound. Furthermore, model selection is performed based on model complexity and goodness of fit. The performance of the framework on the fibercup phantom and human data was compared to the open source diffusion MRI toolkit Camino for a range of SNRs. Performance was quantified by using the Tractometer measures in the fibercup phantom and by comparing streamline counts of lateral projections of the corpus callosum (CC) in the human data. On the phantom data, the comparison showed that our method performs similar to Camino in crossing fiber regions, whilst performing better in a region with kissing fibers (median angular error of 0.73ı vs 2.7ı, valid connections of 57% vs 21% when seed is in the corresponding region of interest). Furthermore, the amount of counts in the lateral projections was found to be higher using our method (19–89% increase depending on a subject). Altogether, our method outperforms the reference method on both phantom and human data allowing for in-vivo probabilistic multi fiber tractography with an objective model selection procedure.
AB - Fiber tractography aims to reconstruct white matter (WM) connections in the brain. Challenges in these reconstructions include estimation of the fiber orientations in regions with multiple fiber populations, and the uncertainty in the fiber orientations as a result of noise. In this work, we use a range of multi-tensor models to cope with crossing fibers. The uncertainty in fiber orientation is captured using the Cramér-Rao lower bound. Furthermore, model selection is performed based on model complexity and goodness of fit. The performance of the framework on the fibercup phantom and human data was compared to the open source diffusion MRI toolkit Camino for a range of SNRs. Performance was quantified by using the Tractometer measures in the fibercup phantom and by comparing streamline counts of lateral projections of the corpus callosum (CC) in the human data. On the phantom data, the comparison showed that our method performs similar to Camino in crossing fiber regions, whilst performing better in a region with kissing fibers (median angular error of 0.73ı vs 2.7ı, valid connections of 57% vs 21% when seed is in the corresponding region of interest). Furthermore, the amount of counts in the lateral projections was found to be higher using our method (19–89% increase depending on a subject). Altogether, our method outperforms the reference method on both phantom and human data allowing for in-vivo probabilistic multi fiber tractography with an objective model selection procedure.
UR - http://www.scopus.com/inward/record.url?scp=85087971047&partnerID=8YFLogxK
U2 - https://doi.org/10.1007/978-3-319-73839-0_9
DO - https://doi.org/10.1007/978-3-319-73839-0_9
M3 - Conference contribution
SN - 9783319738383
T3 - Mathematics and Visualization
SP - 117
EP - 128
BT - Computational Diffusion MRI - MICCAI Workshop, 2017
A2 - Kaden, Enrico
A2 - Grussu, Francesco
A2 - Ning, Lipeng
A2 - Tax, Chantal M.W.
A2 - Veraart, Jelle
PB - Springer
Y2 - 10 September 2017 through 10 September 2017
ER -