Tractography dissection variability: what happens when 42 groups dissect 14 white matter bundles on the same dataset?

Schilling, Kurt G.; Rheault, François; Petit, Laurent; Hansen, Colin B.; Nath, Vishwesh; Yeh, Fang‐Cheng; Girard, Gabriel; Baraković, Muhamed; Rafael-Patiño, Jonathan; Yu, Thomas; Fischi-Gómez, Elda; Pizzolato, Marco; Ocampo-Pineda, Mario; Schiavi, Simona; Canales‐Rodríguez, Erick J.; Daducci, Alessandro; Granziera, Cristina; Innocenti, Giorgio M.; Thiran, Jean‐Philippe; Mancini, Laura; Wastling, Stephen; Cocozza, Sirio; Petracca, Maria; Pontillo, Giuseppe; Mancini, Matteo; Vos, Sjoerd B.; Vakharia, Vejay N.; Duncan, John; Melero, Helena; Manzanedo, Lidia; Sanz‐Morales, Emilio; Peña-Melián, Ángel; Calamante, Fernando; Attyé, Arnaud; Cabeen, Ryan P.; Korobova, Laura; Toga, Arthur W.; Vijayakumari, Anupa A.; Parker, Drew; Verma, Ragini; Radwan, Ahmed; Sunaert, Stefan; Emsell, Louise; Luca, Alberto De; Leemans, Alexander; Bajada, Claude J.; Haroon, Hamied; Azadbakht, Hojjatollah; Chamberland, Maxime; Genc, Sila; Tax, Chantal M. W.; Yeh, Ping‐Hong; Srikanchana, Rujirutana; McKnight, Colin D.; Yang, Joseph Yuan-Mou; Chen, Jian; Kelly, Claire E.; Yeh, Chun‐Hung; Cochereau, Jérôme; Maller, Jerome Joseph; Welton, Thomas; Almairac, Fabien; Seunarine, Kiran K.; Clark, Chris A.; Zhang, Fan; Makris, Nikos; Golby, Alexandra J.; Rathi, Yogesh; O’Donnell, Lauren J.; Xia, Yihao; Aydogan, Dogu Baran; Shi, Yonggang; Fernandes, Francisco Guerreiro; Raemaekers, Mathijs; Warrington, Shaun; Michielse, Stijn; Ramírez-Manzanares, Alonso; Concha, Luis; Aranda, Ramón; Meraz, Mariano Rivera; Lerma-Usabiaga, Garikoitz; Roitman, Lucas Agudiez; Fekonja, Lucius S.; Calarco, Navona; Joseph, Michael; Nakua, Hajer; Voineskos, Aristotle N.; Karan, Philippe; Grenier, Gabrielle; Legarreta, Jon Haitz; Adluru, Nagesh; Nair, Veena A.; Prabhakaran, Vivek; Alexander, Andrew L.; Kamagata, Koji; Saito, Yuya; Uchida, Wataru; Andica, Christina; Abe, Masahiro; Bayrak, Roza G.; Wheeler-Kingshott, Claudia A. M.; D’Angelo, Egidio; Palesi, Fulvia; Savini, Giovanni; Rolandi, Nicolò; Guevara, Pamela; Houenou, Josselin; López-López, Narciso; Mangin, Jean‐François; Poupon, Cyril; Román, Claudio; Vázquez, Andrea; Maffei, Chiara; Arantes, Mavilde; Andrade, José Paulo; Silva, Susana Maria; Calhoun, Vince D.; Caverzasi, Eduardo; Sacco, Simone; Lauricella, Michael; Pestilli, Franco; Bullock, Daniel; Zhan, Yang; Brignoni-Pérez, Edith; Lebel, Catherine; Reynolds, Jess E.; Nestrašil, Igor; Labounek, René; Lenglet, Christophe; Paulson, Amy; Aulická, Štefánia; Heilbronner, Sarah R.; Heuer, Katja; Chandio, Bramsh Qamar; Guaje, Javier; Tang, Wei; Garyfallidis, Eleftherios; Raja, Rajikha; Anderson, Adam W.; Landman, Bennett A.; Descoteaux, Maxime

doi:10.1101/2020.10.07.321083

Cited by 35 publications

(52 citation statements)

References 66 publications

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“…Subject robustness remains high despite differences in the spatial extent of bundles. We replicated previous findings that the definition of major bundles can vary in terms of their spatial extent (quantified via wDSC) (13,35,41,47), depending on the software implementation or the ODF model used. As we show, low wDSC robustness often corresponds to low profile robustness, and vice versa ( Fig 6B,C, Fig 4A,B, and Fig 5A,B).…”

Section: Robustness Of Tractometrysupporting

confidence: 86%

“…Previous work has called into question the the reliability of neuroimaging analysis (e.g., (24,41,42)). We assessed the reliability of a specific approach, tractometry, which is grounded in decades of anatomical knowledge, and we demonstrate that this approach is reproducible, reliable and robust.…”

Section: Discussionmentioning

confidence: 99%

“…There are still significant challenges to robustness that arise from the way in which the major bundles are defined. This problem was highlighted in recent work that demonstrated that different researchers use different criteria to define bundles of streamlines that represent the same tract (41). In our case, this challenge is represented by the relatively low robustness between the waypoint ROI algorithm for bundle definition and the RecoBundles algorithm.…”

Section: Robustness Of Tractometrymentioning

confidence: 91%

“…As highlighted in the recent work by Botvinik-Nezer et al (24) and in parallel by Schilling et al (41), inferences from even a single dataset can vary significantly, depending on the decisions and analysis pipelines that are used.The analysis approaches used in tractometry embody many assumptions made at the different stages of analysis: the model of the signal in each individual voxel, the manner in which streamlines are generated in tractography, the definition of bundles, and the extraction of tract profiles. While TRR is important, it does not guard against systematic errors in the analysis approach.…”

Section: Robustness Of Tractometrymentioning

confidence: 99%

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Evaluating the reliability of human brain white matter tractometry

Kruper

Yeatman

Richie-Halford

et al. 2021

Preprint

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The validity of research results depends on the reliability of analysis methods. In recent years, there have been concerns about the validity of research that uses diffusion-weighted MRI (dMRI) to understand human brain white matter connections in vivo, in part based on reliability of the analysis methods used in this field. We defined and assessed three dimensions of reliability in dMRI-based tractometry, an analysis technique that assesses the physical properties of white matter pathways: (1) reproducibility, (2) test-retest reliability and (3) robustness. To facilitate reproducibility, we provide software that automates tractometry (https://yeatmanlab.github.io/pyAFQ). In measurements from the Human Connectome Project, as well as clinical-grade measurements, we find that tractometry has high test-retest reliability that is comparable to most standardized clinical assessment tools. We find that tractometry is also robust: showing high reliability with different choices of analysis algorithms. Taken together, our results suggest that tractometry is a reliable approach to analysis of white matter connections. The overall approach taken here both demonstrates the specific trustworthiness of tractometry analysis and outlines what researchers can do to demonstrate the reliability of computational analysis pipelines in neuroimaging.

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Section: Robustness Of Tractometrysupporting

confidence: 86%

Section: Discussionmentioning

confidence: 99%

Section: Robustness Of Tractometrymentioning

confidence: 91%

Section: Robustness Of Tractometrymentioning

confidence: 99%

See 2 more Smart Citations

Evaluating the reliability of human brain white matter tractometry

Kruper

Yeatman

Richie-Halford

et al. 2021

Preprint

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“…The review is meant to provide a primer, a lookup table for students, educators and researchers interested in white matter by providing an introduction without dwelling on the technical aspects of any of the specific subfields that are involved in continuously contributing knowledge to understanding white matter. It is our hope that we are able to facilitate the expedited formation of a consensus white matter taxonomy (Schilling et al, 2020a). We suggest, as others have, that the formation of such a consensus is an important and necessary precursor to the widespread adoption of investigations of white matter as a standard component of neurobiological accounts of behavior, brain disorders, and changes in cognition across the lifespan.…”

Section: Introductionmentioning

confidence: 74%

A taxonomy of the brain’s white matter: Twenty-one major tracts for the twenty-first century

Bullock¹,

Ea²,

Grier³

et al. 2021

Preprint

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The functional and computational properties of brain areas are determined, in large part, by their connectivity profiles. Advances in neuroimaging and network neuroscience allow us to characterize the human brain noninvasively and in vivo, but a comprehensive understanding of the human brain demands an account of the anatomy of brain connections. Long-range anatomical connections are instantiated by white matter and organized into tracts. Here, we aim to characterize the connections, morphology, traversal, and functions of the major white matter tracts in the brain. It is clear that there are significant discrepancies across different accounts of white matter tract anatomy, hindering our attempts to accurately map the connectivity of the human brain. We thoroughly synthesize accounts from multiple methods, but especially nonhuman primate tract-tracing and human diffusion tractography. Ultimately, we suggest that our synthesis provides an essential reference for neuroscientists and clinicians interested in brain connectivity and anatomy, allowing for the study of the association of white matter’s macro and microstructural properties with behavior, development, and disordered processes.

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Tractostorm 2: Optimizing tractography dissection reproducibility with segmentation protocol dissemination

Rheault

Schilling

Valcourt-Caron

et al. 2022

Human Brain Mapping

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The segmentation of brain structures is a key component of many neuroimaging studies. Consistent anatomical definitions are crucial to ensure consensus on the position and shape of brain structures, but segmentations are prone to variation in their interpretation and execution. White-matter (WM) pathways are global structures of the brain defined by local landmarks, which leads to anatomical definitions being difficult

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Tractography dissection variability: what happens when 42 groups dissect 14 white matter bundles on the same dataset?

Cited by 35 publications

References 66 publications

Evaluating the reliability of human brain white matter tractometry

Evaluating the reliability of human brain white matter tractometry

A taxonomy of the brain’s white matter: Twenty-one major tracts for the twenty-first century

Tractostorm 2: Optimizing tractography dissection reproducibility with segmentation protocol dissemination

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