Your search keyword '"Guaje J"' showing total 7 results

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

Author

Schilling, KG, Rheault, F, Petit, L, Hansen, CB, Nath, V, Yeh, F-C, Girard, G, Barakovic, M, Rafael-Patino, J, Yu, T, Fischi-Gomez, E, Pizzolato, M, Ocampo-Pineda, M, Schiavi, S, Canales-Rodriguez, EJ, Daducci, A, Granziera, C, Innocenti, G, Thiran, J-P, Mancini, L, Wastling, S, Cocozza, S, Petracca, M, Pontillo, G, Mancini, M, Vos, SB, Vakharia, VN, Duncan, JS, Melero, H, Manzanedo, L, Sanz-Morales, E, Pena-Melian, A, Calamante, F, Attye, A, Cabeen, RP, Korobova, L, Toga, AW, Vijayakumari, AA, Parker, D, Verma, R, Radwan, A, Sunaert, S, Emsell, L, De Luca, A, Leemans, A, Bajada, CJ, Haroon, H, Azadbakht, H, Chamberland, M, Genc, S, Tax, CMW, Yeh, P-H, Srikanchana, R, Mcknight, CD, Yang, JY-M, Chen, J, Kelly, CE, Yeh, C-H, Cochereau, J, Maller, JJ, Welton, T, Almairac, F, Seunarine, KK, Clark, CA, Zhang, F, Makris, N, Golby, A, Rathi, Y, O'Donnell, LJ, Xia, Y, Aydogan, DB, Shi, Y, Fernandes, FG, Raemaekers, M, Warrington, S, Michielse, S, Ramirez-Manzanares, A, Concha, L, Aranda, R, Meraz, MR, Lerma-Usabiaga, G, Roitman, L, Fekonja, LS, Calarco, N, Joseph, M, Nakua, H, Voineskos, AN, Karan, P, Grenier, G, Legarreta, JH, Adluru, N, Nair, VA, Prabhakaran, V, Alexander, AL, Kamagata, K, Saito, Y, Uchida, W, Andica, C, Abe, M, Bayrak, RG, Wheeler-Kingshott, CAMG, D'Angelo, E, Palesi, F, Savini, G, Rolandi, N, Guevara, P, Houenou, J, Lopez-Lopez, N, Mangin, J-F, Poupon, C, Roman, C, Vazquez, A, Maffei, C, Arantes, M, Andrade, JP, Silva, SM, Calhoun, VD, Caverzasi, E, Sacco, S, Lauricella, M, Pestilli, F, Bullock, D, Zhan, Y, Brignoni-Perez, E, Lebel, C, Reynolds, JE, Nestrasil, I, Labounek, R, Lenglet, C, Paulson, A, Aulicka, S, Heilbronner, SR, Heuer, K, Chandio, BQ, Guaje, J, Tang, W, Garyfallidis, E, Raja, R, Anderson, AW, Landman, BA, Descoteaux, M, Schilling, KG, Rheault, F, Petit, L, Hansen, CB, Nath, V, Yeh, F-C, Girard, G, Barakovic, M, Rafael-Patino, J, Yu, T, Fischi-Gomez, E, Pizzolato, M, Ocampo-Pineda, M, Schiavi, S, Canales-Rodriguez, EJ, Daducci, A, Granziera, C, Innocenti, G, Thiran, J-P, Mancini, L, Wastling, S, Cocozza, S, Petracca, M, Pontillo, G, Mancini, M, Vos, SB, Vakharia, VN, Duncan, JS, Melero, H, Manzanedo, L, Sanz-Morales, E, Pena-Melian, A, Calamante, F, Attye, A, Cabeen, RP, Korobova, L, Toga, AW, Vijayakumari, AA, Parker, D, Verma, R, Radwan, A, Sunaert, S, Emsell, L, De Luca, A, Leemans, A, Bajada, CJ, Haroon, H, Azadbakht, H, Chamberland, M, Genc, S, Tax, CMW, Yeh, P-H, Srikanchana, R, Mcknight, CD, Yang, JY-M, Chen, J, Kelly, CE, Yeh, C-H, Cochereau, J, Maller, JJ, Welton, T, Almairac, F, Seunarine, KK, Clark, CA, Zhang, F, Makris, N, Golby, A, Rathi, Y, O'Donnell, LJ, Xia, Y, Aydogan, DB, Shi, Y, Fernandes, FG, Raemaekers, M, Warrington, S, Michielse, S, Ramirez-Manzanares, A, Concha, L, Aranda, R, Meraz, MR, Lerma-Usabiaga, G, Roitman, L, Fekonja, LS, Calarco, N, Joseph, M, Nakua, H, Voineskos, AN, Karan, P, Grenier, G, Legarreta, JH, Adluru, N, Nair, VA, Prabhakaran, V, Alexander, AL, Kamagata, K, Saito, Y, Uchida, W, Andica, C, Abe, M, Bayrak, RG, Wheeler-Kingshott, CAMG, D'Angelo, E, Palesi, F, Savini, G, Rolandi, N, Guevara, P, Houenou, J, Lopez-Lopez, N, Mangin, J-F, Poupon, C, Roman, C, Vazquez, A, Maffei, C, Arantes, M, Andrade, JP, Silva, SM, Calhoun, VD, Caverzasi, E, Sacco, S, Lauricella, M, Pestilli, F, Bullock, D, Zhan, Y, Brignoni-Perez, E, Lebel, C, Reynolds, JE, Nestrasil, I, Labounek, R, Lenglet, C, Paulson, A, Aulicka, S, Heilbronner, SR, Heuer, K, Chandio, BQ, Guaje, J, Tang, W, Garyfallidis, E, Raja, R, Anderson, AW, Landman, BA, and Descoteaux, M

Abstract

White matter bundle segmentation using diffusion MRI fiber tractography has become the method of choice to identify white matter fiber pathways in vivo in human brains. However, like other analyses of complex data, there is considerable variability in segmentation protocols and techniques. This can result in different reconstructions of the same intended white matter pathways, which directly affects tractography results, quantification, and interpretation. In this study, we aim to evaluate and quantify the variability that arises from different protocols for bundle segmentation. Through an open call to users of fiber tractography, including anatomists, clinicians, and algorithm developers, 42 independent teams were given processed sets of human whole-brain streamlines and asked to segment 14 white matter fascicles on six subjects. In total, we received 57 different bundle segmentation protocols, which enabled detailed volume-based and streamline-based analyses of agreement and disagreement among protocols for each fiber pathway. Results show that even when given the exact same sets of underlying streamlines, the variability across protocols for bundle segmentation is greater than all other sources of variability in the virtual dissection process, including variability within protocols and variability across subjects. In order to foster the use of tractography bundle dissection in routine clinical settings, and as a fundamental analytical tool, future endeavors must aim to resolve and reduce this heterogeneity. Although external validation is needed to verify the anatomical accuracy of bundle dissections, reducing heterogeneity is a step towards reproducible research and may be achieved through the use of standard nomenclature and definitions of white matter bundles and well-chosen constraints and decisions in the dissection process.

Published

2021

2. Author Correction: brainlife.io: a decentralized and open-source cloud platform to support neuroscience research.

Author

Hayashi S, Caron BA, Heinsfeld AS, Vinci-Booher S, McPherson B, Bullock DN, Bertò G, Niso G, Hanekamp S, Levitas D, Ray K, MacKenzie A, Avesani P, Kitchell L, Leong JK, Nascimento-Silva F, Koudoro S, Willis H, Jolly JK, Pisner D, Zuidema TR, Kurzawski JW, Mikellidou K, Bussalb A, Chaumon M, George N, Rorden C, Victory C, Bhatia D, Aydogan DB, Yeh FF, Delogu F, Guaje J, Veraart J, Fischer J, Faskowitz J, Fabrega R, Hunt D, McKee S, Brown ST, Heyman S, Iacovella V, Mejia AF, Marinazzo D, Craddock RC, Olivetti E, Hanson JL, Garyfallidis E, Stanzione D, Carson J, Henschel R, Hancock DY, Stewart CA, Schnyer D, Eke DO, Poldrack RA, Bollmann S, Stewart A, Bridge H, Sani I, Freiwald WA, Puce A, Port NL, and Pestilli F

Published

2024

3. brainlife.io: a decentralized and open-source cloud platform to support neuroscience research.

Author

Hayashi S, Caron BA, Heinsfeld AS, Vinci-Booher S, McPherson B, Bullock DN, Bertò G, Niso G, Hanekamp S, Levitas D, Ray K, MacKenzie A, Avesani P, Kitchell L, Leong JK, Nascimento-Silva F, Koudoro S, Willis H, Jolly JK, Pisner D, Zuidema TR, Kurzawski JW, Mikellidou K, Bussalb A, Chaumon M, George N, Rorden C, Victory C, Bhatia D, Aydogan DB, Yeh FF, Delogu F, Guaje J, Veraart J, Fischer J, Faskowitz J, Fabrega R, Hunt D, McKee S, Brown ST, Heyman S, Iacovella V, Mejia AF, Marinazzo D, Craddock RC, Olivetti E, Hanson JL, Garyfallidis E, Stanzione D, Carson J, Henschel R, Hancock DY, Stewart CA, Schnyer D, Eke DO, Poldrack RA, Bollmann S, Stewart A, Bridge H, Sani I, Freiwald WA, Puce A, Port NL, and Pestilli F

Subjects

Humans, Neuroimaging methods, Reproducibility of Results, Software, Brain physiology, Brain diagnostic imaging, Neurosciences methods, Cloud Computing

Abstract

Neuroscience is advancing standardization and tool development to support rigor and transparency. Consequently, data pipeline complexity has increased, hindering FAIR (findable, accessible, interoperable and reusable) access. brainlife.io was developed to democratize neuroimaging research. The platform provides data standardization, management, visualization and processing and automatically tracks the provenance history of thousands of data objects. Here, brainlife.io is described and evaluated for validity, reliability, reproducibility, replicability and scientific utility using four data modalities and 3,200 participants., (© 2024. The Author(s).)

Published

2024

4. brainlife.io : A decentralized and open source cloud platform to support neuroscience research.

Author

Hayashi S, Caron BA, Heinsfeld AS, Vinci-Booher S, McPherson B, Bullock DN, Bertò G, Niso G, Hanekamp S, Levitas D, Ray K, MacKenzie A, Kitchell L, Leong JK, Nascimento-Silva F, Koudoro S, Willis H, Jolly JK, Pisner D, Zuidema TR, Kurzawski JW, Mikellidou K, Bussalb A, Rorden C, Victory C, Bhatia D, Baran Aydogan D, Yeh FF, Delogu F, Guaje J, Veraart J, Bollman S, Stewart A, Fischer J, Faskowitz J, Chaumon M, Fabrega R, Hunt D, McKee S, Brown ST, Heyman S, Iacovella V, Mejia AF, Marinazzo D, Craddock RC, Olivetti E, Hanson JL, Avesani P, Garyfallidis E, Stanzione D, Carson J, Henschel R, Hancock DY, Stewart CA, Schnyer D, Eke DO, Poldrack RA, George N, Bridge H, Sani I, Freiwald WA, Puce A, Port NL, and Pestilli F

Abstract

Neuroscience research has expanded dramatically over the past 30 years by advancing standardization and tool development to support rigor and transparency. Consequently, the complexity of the data pipeline has also increased, hindering access to FAIR data analysis to portions of the worldwide research community. brainlife.io was developed to reduce these burdens and democratize modern neuroscience research across institutions and career levels. Using community software and hardware infrastructure, the platform provides open-source data standardization, management, visualization, and processing and simplifies the data pipeline. brainlife.io automatically tracks the provenance history of thousands of data objects, supporting simplicity, efficiency, and transparency in neuroscience research. Here brainlife.io's technology and data services are described and evaluated for validity, reliability, reproducibility, replicability, and scientific utility. Using data from 4 modalities and 3,200 participants, we demonstrate that brainlife.io's services produce outputs that adhere to best practices in modern neuroscience research., Competing Interests: Competing interests. The authors declare no competing financial interests.

Published

2023

5. Horizon, closing the gap between cinematic visualization and medical imaging.

Author

Guaje J, Koudoro S, and Garyfallidis E

Abstract

Medical imaging has become a fascinating field with detailed visualizations of the body's internal environments. Although the field has grown fast and is sensitive to new technologies, it does not use the latest rendering techniques available in other domains, such as day-to-day movie production or game development. In this work, we bring forward Horizon, a new engine that provides cinematic rendering capabilities in real-time for quality controlling medical data. In addition, Horizon is provided as free, open-source software to be used as a foundation stone for building the next generation of medical imaging applications. In this introductory paper, we focus on the extensive development of advanced shaders, which can be used to highlight untapped features of the data and allow fast interaction with machine learning algorithms. In addition, Horizon provides physically-based rendering capabilities, the epitome of advanced visualization, adapted for the needs of medical imaging analysis practices.

Published

2023

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

Author

Schilling KG, Rheault F, Petit L, Hansen CB, Nath V, Yeh FC, Girard G, Barakovic M, Rafael-Patino J, Yu T, Fischi-Gomez E, Pizzolato M, Ocampo-Pineda M, Schiavi S, Canales-Rodríguez EJ, Daducci A, Granziera C, Innocenti G, Thiran JP, Mancini L, Wastling S, Cocozza S, Petracca M, Pontillo G, Mancini M, Vos SB, Vakharia VN, Duncan JS, Melero H, Manzanedo L, Sanz-Morales E, Peña-Melián Á, Calamante F, Attyé A, Cabeen RP, Korobova L, Toga AW, Vijayakumari AA, Parker D, Verma R, Radwan A, Sunaert S, Emsell L, De Luca A, Leemans A, Bajada CJ, Haroon H, Azadbakht H, Chamberland M, Genc S, Tax CMW, Yeh PH, Srikanchana R, Mcknight CD, Yang JY, Chen J, Kelly CE, Yeh CH, Cochereau J, Maller JJ, Welton T, Almairac F, Seunarine KK, Clark CA, Zhang F, Makris N, Golby A, Rathi Y, O'Donnell LJ, Xia Y, Aydogan DB, Shi Y, Fernandes FG, Raemaekers M, Warrington S, Michielse S, Ramírez-Manzanares A, Concha L, Aranda R, Meraz MR, Lerma-Usabiaga G, Roitman L, Fekonja LS, Calarco N, Joseph M, Nakua H, Voineskos AN, Karan P, Grenier G, Legarreta JH, Adluru N, Nair VA, Prabhakaran V, Alexander AL, Kamagata K, Saito Y, Uchida W, Andica C, Abe M, Bayrak RG, Wheeler-Kingshott CAMG, D'Angelo E, Palesi F, Savini G, Rolandi N, Guevara P, Houenou J, López-López N, Mangin JF, Poupon C, Román C, Vázquez A, Maffei C, Arantes M, Andrade JP, Silva SM, Calhoun VD, Caverzasi E, Sacco S, Lauricella M, Pestilli F, Bullock D, Zhan Y, Brignoni-Perez E, Lebel C, Reynolds JE, Nestrasil I, Labounek R, Lenglet C, Paulson A, Aulicka S, Heilbronner SR, Heuer K, Chandio BQ, Guaje J, Tang W, Garyfallidis E, Raja R, Anderson AW, Landman BA, and Descoteaux M

Subjects

Algorithms, Humans, Image Processing, Computer-Assisted methods, Neural Pathways diagnostic imaging, Diffusion Tensor Imaging methods, Dissection methods, White Matter diagnostic imaging

Abstract

White matter bundle segmentation using diffusion MRI fiber tractography has become the method of choice to identify white matter fiber pathways in vivo in human brains. However, like other analyses of complex data, there is considerable variability in segmentation protocols and techniques. This can result in different reconstructions of the same intended white matter pathways, which directly affects tractography results, quantification, and interpretation. In this study, we aim to evaluate and quantify the variability that arises from different protocols for bundle segmentation. Through an open call to users of fiber tractography, including anatomists, clinicians, and algorithm developers, 42 independent teams were given processed sets of human whole-brain streamlines and asked to segment 14 white matter fascicles on six subjects. In total, we received 57 different bundle segmentation protocols, which enabled detailed volume-based and streamline-based analyses of agreement and disagreement among protocols for each fiber pathway. Results show that even when given the exact same sets of underlying streamlines, the variability across protocols for bundle segmentation is greater than all other sources of variability in the virtual dissection process, including variability within protocols and variability across subjects. In order to foster the use of tractography bundle dissection in routine clinical settings, and as a fundamental analytical tool, future endeavors must aim to resolve and reduce this heterogeneity. Although external validation is needed to verify the anatomical accuracy of bundle dissections, reducing heterogeneity is a step towards reproducible research and may be achieved through the use of standard nomenclature and definitions of white matter bundles and well-chosen constraints and decisions in the dissection process., (Copyright © 2021. Published by Elsevier Inc.)

Published

2021

7. A method for functional network connectivity using distance correlation.

Author

Rudas J, Guaje J, Demertzi A, Heine L, Tshibanda L, Soddu A, Laureys S, and Gomez F

Subjects

Adult, Aged, Case-Control Studies, Consciousness, Female, Humans, Magnetic Resonance Imaging methods, Male, Middle Aged, Nerve Net physiopathology, Persistent Vegetative State physiopathology

Abstract

In this paper, we present a novel approach for functional network connectivity in fMRI resting activity using distance correlation. The proposed method accounts for nonlinear relationships between the resting state networks and can be used for both single subject and group level analyses. We showed that the new strategy improves the capacity of characterization of pathological populations, such as, patients with disorder of consciousness, when compared to related approaches.

Published

2014