Insights from the IronTract challenge: Optimal methods for mapping brain pathways from multi-shell diffusion MRI

doi:10.1016/j.neuroimage.2022.119327

Insights from the IronTract challenge: Optimal methods for mapping brain pathways from multi-shell diffusion MRI

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Abstract

Limitations in the accuracy of brain pathways reconstructed by diffusion MRI (dMRI) tractography have received considerable attention. While the technical advances spearheaded by the Human Connectome Project (HCP) led to significant improvements in dMRI data quality, it remains unclear how these data should be analyzed to maximize tractography accuracy. Over a period of two years, we have engaged the dMRI community in the IronTract Challenge, which aims to answer this question by leveraging a unique dataset. Macaque brains that have received both tracer injections and ex vivo dMRI at high spatial and angular resolution allow a comprehensive, quantitative assessment of tractography accuracy on state-of-the-art dMRI acquisition schemes. We find that, when analysis methods are carefully optimized, the HCP scheme can achieve similar accuracy as a more time-consuming, Cartesian-grid scheme. Importantly, we show that simple pre- and post-processing strategies can improve the accuracy and robustness of many tractography methods. Finally, we find that fiber configurations that go beyond crossing (e.g., fanning, branching) are the most challenging for tractography. The IronTract Challenge remains open and we hope that it can serve as a valuable validation tool for both users and developers of dMRI analysis methods.

Original language	English
Article number	119327
Pages (from-to)	1-17
Journal	NeuroImage
Volume	257
DOIs	https://doi.org/10.1016/j.neuroimage.2022.119327
Publication status	Published - 15 Aug 2022

Keywords

Brain/diagnostic imaging
Connectome/methods
Diffusion
Diffusion Magnetic Resonance Imaging/methods
Diffusion Tensor Imaging/methods
Humans
Image Processing, Computer-Assisted/methods
White Matter
Validation
Anatomic tracing
Tractography
White matter anatomy
Diffusion MRI

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10.1016/j.neuroimage.2022.119327Licence: CC BY-NC-ND

1-s2.0-S1053811922004463-mainFinal published version, 5.02 MBLicence: CC BY-NC-ND

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@article{4cd3a70501f14c14a43a25ad93944934,

title = "Insights from the IronTract challenge: Optimal methods for mapping brain pathways from multi-shell diffusion MRI",

abstract = "Limitations in the accuracy of brain pathways reconstructed by diffusion MRI (dMRI) tractography have received considerable attention. While the technical advances spearheaded by the Human Connectome Project (HCP) led to significant improvements in dMRI data quality, it remains unclear how these data should be analyzed to maximize tractography accuracy. Over a period of two years, we have engaged the dMRI community in the IronTract Challenge, which aims to answer this question by leveraging a unique dataset. Macaque brains that have received both tracer injections and ex vivo dMRI at high spatial and angular resolution allow a comprehensive, quantitative assessment of tractography accuracy on state-of-the-art dMRI acquisition schemes. We find that, when analysis methods are carefully optimized, the HCP scheme can achieve similar accuracy as a more time-consuming, Cartesian-grid scheme. Importantly, we show that simple pre- and post-processing strategies can improve the accuracy and robustness of many tractography methods. Finally, we find that fiber configurations that go beyond crossing (e.g., fanning, branching) are the most challenging for tractography. The IronTract Challenge remains open and we hope that it can serve as a valuable validation tool for both users and developers of dMRI analysis methods.",

keywords = "Brain/diagnostic imaging, Connectome/methods, Diffusion, Diffusion Magnetic Resonance Imaging/methods, Diffusion Tensor Imaging/methods, Humans, Image Processing, Computer-Assisted/methods, White Matter, Validation, Anatomic tracing, Tractography, White matter anatomy, Diffusion MRI",

author = "Chiara Maffei and Gabriel Girard and Schilling, {Kurt G} and Aydogan, {Dogu Baran} and Nagesh Adluru and Andrey Zhylka and Ye Wu and Matteo Mancini and Andac Hamamci and Alessia Sarica and Achille Teillac and Baete, {Steven H} and Davood Karimi and Fang-Cheng Yeh and Yildiz, {Mert E} and Ali Gholipour and Yann Bihan-Poudec and Bassem Hiba and Andrea Quattrone and Aldo Quattrone and Tommy Boshkovski and Nikola Stikov and Pew-Thian Yap and {de Luca}, Alberto and Josien Pluim and Alexander Leemans and Vivek Prabhakaran and Bendlin, {Barbara B} and Alexander, {Andrew L} and Landman, {Bennett A} and Canales-Rodr{\'i}guez, {Erick J} and Muhamed Barakovic and Jonathan Rafael-Patino and Thomas Yu and Ga{\"e}tan Rensonnet and Simona Schiavi and Alessandro Daducci and Marco Pizzolato and Elda Fischi-Gomez and Jean-Philippe Thiran and George Dai and Giorgia Grisot and Nikola Lazovski and Santi Puch and Marc Ramos and Paulo Rodrigues and Vesna Pr{\v c}kovska and Robert Jones and Julia Lehman and Haber, {Suzanne N}",

note = "Funding Information: Data acquisition was supported by the National Institute of Mental Health (R01-MH045573, P50-MH106435). Additional research support was provided by the National Institute of Biomedical Imaging and Bioengineering (R01-EB021265) and the National Institute of Neurological Disorders and Stroke (R01-NS119911). Imaging was carried out at the Athinoula A. Martinos Center for Biomedical Imaging at the Massachusetts General Hospital, using resources provided by the Center for Functional Neuroimaging Technologies, P41-EB015896, a P41 Biotechnology Resource Grant, and instrumentation supported by the NIH Shared Instrumentation Grant Program (S10RR016811, S10RR023401, S10RR019307, and S10RR023043). Andrey Zhylka is supported by the European Union's Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant (765148). Ye Wu and Pew-Thian Yap were supported in part by the National Institute of Mental Health (R01-MH125479), and the National Institute of Biomedical Imaging and Bioengineering (R01-EB008374). The team at Boston Children's Hospital was supported in part by the National Institutes of Health (NIH) grants R01-NS106030, R01-EB031849, and R01-EB019483. Team from UW-Madison would like to acknowledge the NIH grants R01NS123378, U54HD090256, R01NS092870, R01EB022883, R01AI117924, R01AG027161, RF1AG059312, P50AG033514, R01NS105646, UF1AG051216, R01NS111022, R01NS117568, P01AI132132, R01AI138647, R34DA050258, and R01AG037639. Erick J. Canales-Rodr{\'i}guez was supported by the Swiss National Science Foundation, Ambizione grant PZ00P2_185814. Matteo Mancini was funded by the Wellcome Trust through a Sir Henry Wellcome Postdoctoral Fellowship [213722/Z/18/Z]. Publisher Copyright: {\textcopyright} 2022",

year = "2022",

month = aug,

day = "15",

doi = "10.1016/j.neuroimage.2022.119327",

language = "English",

volume = "257",

pages = "1--17",

journal = "NeuroImage",

issn = "1053-8119",

publisher = "Academic Press Inc.",

}

TY - JOUR

T1 - Insights from the IronTract challenge

T2 - Optimal methods for mapping brain pathways from multi-shell diffusion MRI

AU - Maffei, Chiara

AU - Girard, Gabriel

AU - Schilling, Kurt G

AU - Aydogan, Dogu Baran

AU - Adluru, Nagesh

AU - Zhylka, Andrey

AU - Wu, Ye

AU - Mancini, Matteo

AU - Hamamci, Andac

AU - Sarica, Alessia

AU - Teillac, Achille

AU - Baete, Steven H

AU - Karimi, Davood

AU - Yeh, Fang-Cheng

AU - Yildiz, Mert E

AU - Gholipour, Ali

AU - Bihan-Poudec, Yann

AU - Hiba, Bassem

AU - Quattrone, Andrea

AU - Quattrone, Aldo

AU - Boshkovski, Tommy

AU - Stikov, Nikola

AU - Yap, Pew-Thian

AU - de Luca, Alberto

AU - Pluim, Josien

AU - Leemans, Alexander

AU - Prabhakaran, Vivek

AU - Bendlin, Barbara B

AU - Alexander, Andrew L

AU - Landman, Bennett A

AU - Canales-Rodríguez, Erick J

AU - Barakovic, Muhamed

AU - Rafael-Patino, Jonathan

AU - Yu, Thomas

AU - Rensonnet, Gaëtan

AU - Schiavi, Simona

AU - Daducci, Alessandro

AU - Pizzolato, Marco

AU - Fischi-Gomez, Elda

AU - Thiran, Jean-Philippe

AU - Dai, George

AU - Grisot, Giorgia

AU - Lazovski, Nikola

AU - Puch, Santi

AU - Ramos, Marc

AU - Rodrigues, Paulo

AU - Prčkovska, Vesna

AU - Jones, Robert

AU - Lehman, Julia

AU - Haber, Suzanne N

N1 - Funding Information: Data acquisition was supported by the National Institute of Mental Health (R01-MH045573, P50-MH106435). Additional research support was provided by the National Institute of Biomedical Imaging and Bioengineering (R01-EB021265) and the National Institute of Neurological Disorders and Stroke (R01-NS119911). Imaging was carried out at the Athinoula A. Martinos Center for Biomedical Imaging at the Massachusetts General Hospital, using resources provided by the Center for Functional Neuroimaging Technologies, P41-EB015896, a P41 Biotechnology Resource Grant, and instrumentation supported by the NIH Shared Instrumentation Grant Program (S10RR016811, S10RR023401, S10RR019307, and S10RR023043). Andrey Zhylka is supported by the European Union's Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant (765148). Ye Wu and Pew-Thian Yap were supported in part by the National Institute of Mental Health (R01-MH125479), and the National Institute of Biomedical Imaging and Bioengineering (R01-EB008374). The team at Boston Children's Hospital was supported in part by the National Institutes of Health (NIH) grants R01-NS106030, R01-EB031849, and R01-EB019483. Team from UW-Madison would like to acknowledge the NIH grants R01NS123378, U54HD090256, R01NS092870, R01EB022883, R01AI117924, R01AG027161, RF1AG059312, P50AG033514, R01NS105646, UF1AG051216, R01NS111022, R01NS117568, P01AI132132, R01AI138647, R34DA050258, and R01AG037639. Erick J. Canales-Rodríguez was supported by the Swiss National Science Foundation, Ambizione grant PZ00P2_185814. Matteo Mancini was funded by the Wellcome Trust through a Sir Henry Wellcome Postdoctoral Fellowship [213722/Z/18/Z]. Publisher Copyright: © 2022

PY - 2022/8/15

Y1 - 2022/8/15

N2 - Limitations in the accuracy of brain pathways reconstructed by diffusion MRI (dMRI) tractography have received considerable attention. While the technical advances spearheaded by the Human Connectome Project (HCP) led to significant improvements in dMRI data quality, it remains unclear how these data should be analyzed to maximize tractography accuracy. Over a period of two years, we have engaged the dMRI community in the IronTract Challenge, which aims to answer this question by leveraging a unique dataset. Macaque brains that have received both tracer injections and ex vivo dMRI at high spatial and angular resolution allow a comprehensive, quantitative assessment of tractography accuracy on state-of-the-art dMRI acquisition schemes. We find that, when analysis methods are carefully optimized, the HCP scheme can achieve similar accuracy as a more time-consuming, Cartesian-grid scheme. Importantly, we show that simple pre- and post-processing strategies can improve the accuracy and robustness of many tractography methods. Finally, we find that fiber configurations that go beyond crossing (e.g., fanning, branching) are the most challenging for tractography. The IronTract Challenge remains open and we hope that it can serve as a valuable validation tool for both users and developers of dMRI analysis methods.

AB - Limitations in the accuracy of brain pathways reconstructed by diffusion MRI (dMRI) tractography have received considerable attention. While the technical advances spearheaded by the Human Connectome Project (HCP) led to significant improvements in dMRI data quality, it remains unclear how these data should be analyzed to maximize tractography accuracy. Over a period of two years, we have engaged the dMRI community in the IronTract Challenge, which aims to answer this question by leveraging a unique dataset. Macaque brains that have received both tracer injections and ex vivo dMRI at high spatial and angular resolution allow a comprehensive, quantitative assessment of tractography accuracy on state-of-the-art dMRI acquisition schemes. We find that, when analysis methods are carefully optimized, the HCP scheme can achieve similar accuracy as a more time-consuming, Cartesian-grid scheme. Importantly, we show that simple pre- and post-processing strategies can improve the accuracy and robustness of many tractography methods. Finally, we find that fiber configurations that go beyond crossing (e.g., fanning, branching) are the most challenging for tractography. The IronTract Challenge remains open and we hope that it can serve as a valuable validation tool for both users and developers of dMRI analysis methods.

KW - Brain/diagnostic imaging

KW - Connectome/methods

KW - Diffusion

KW - Diffusion Magnetic Resonance Imaging/methods

KW - Diffusion Tensor Imaging/methods

KW - Humans

KW - Image Processing, Computer-Assisted/methods

KW - White Matter

KW - Validation

KW - Anatomic tracing

KW - Tractography

KW - White matter anatomy

KW - Diffusion MRI

UR - http://www.scopus.com/inward/record.url?scp=85131443264&partnerID=8YFLogxK

U2 - 10.1016/j.neuroimage.2022.119327

DO - 10.1016/j.neuroimage.2022.119327

M3 - Article

C2 - 35636227

SN - 1053-8119

VL - 257

SP - 1

EP - 17

JO - NeuroImage

JF - NeuroImage

M1 - 119327

ER -

Insights from the IronTract challenge: Optimal methods for mapping brain pathways from multi-shell diffusion MRI

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Keywords

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