BookR: School of Health Core Facilities Booking
PubMed Publications| Keyword search (4,164 papers available) |  |
"Glatard T" Authored Publications:
| Title | Authors | PubMed ID | |
|---|---|---|---|
| 1 | Hierarchical Storage Management in User Space for Neuroimaging Applications | Hayot-Sasson V; Glatard T; | 41432812 ENCS |
| 2 | Open-source platforms to investigate analytical flexibility in neuroimaging | Sanz-Robinson J; Wang M; McPherson B; Chatelain Y; Kennedy D; Glatard T; Poline JB; | 40800896 ENCS |
| 3 | An analysis of performance bottlenecks in MRI preprocessing | Dugré M; Chatelain Y; Glatard T; | 40072903 ENCS |
| 4 | Predicting Parkinson's disease trajectory using clinical and functional MRI features: A reproduction and replication study | Germani E; Bhagwat N; Dugré M; Gau R; Montillo AA; Nguyen KP; Sokolowski A; Sharp M; Poline JB; Glatard T; | 39982930 ENCS |
| 5 | Registered report: Age-preserved semantic memory and the CRUNCH effect manifested as differential semantic control networks: An fMRI study | Haitas N; Dubuc J; Massé-Leblanc C; Chamberland V; Amiri M; Glatard T; Wilson M; Joanette Y; Steffener J; | 38917084 ENCS |
| 6 | Longitudinal brain structure changes in Parkinson's disease: A replication study | Sokolowski A; Bhagwat N; Chatelain Y; Dugré M; Hanganu A; Monchi O; McPherson B; Wang M; Poline JB; Sharp M; Glatard T; | 38295031 ENCS |
| 7 | Numerical stability of DeepGOPlus inference | Gonzalez Pepe I; Chatelain Y; Kiar G; Glatard T; | 38285635 ENCS |
| 8 | Data and Tools Integration in the Canadian Open Neuroscience Platform | Poline JB; Das S; Glatard T; Madjar C; Dickie EW; Lecours X; Beaudry T; Beck N; Behan B; Brown ST; Bujold D; Beauvais M; Caron B; Czech C; Dharsee M; Dugré M; Evans K; Gee T; Ippoliti G; Kiar G; Knoppers BM; Kuehn T; Le D; Lo D; Mazaheri M; MacFarlane D; Muja N; O' Brien EA; O' Callaghan L; Paiva S; Park P; Quesnel D; Rabelais H; Rioux P; Legault M; Tremblay-Mercier J; Rotenberg D; Stone J; Strauss T; Zaytseva K; Zhou J; Duchesne S; Khan AR; Hill S; Evans AC; | 37024500 ENCS |
| 9 | Numerical uncertainty in analytical pipelines lead to impactful variability in brain networks | Kiar G; Chatelain Y; de Oliveira Castro P; Petit E; Rokem A; Varoquaux G; Misic B; Evans AC; Glatard T; | 34724000 ENCS |
| 10 | Multiple sclerosis lesions segmentation from multiple experts: the MICCAI 2016 challenge dataset | Commowick O; Kain M; Casey R; Ameli R; Ferré JC; Kerbrat A; Tourdias T; Cervenansky F; Camarasu-Pop S; Glatard T; Vukusic S; Edan G; Barillot C; Dojat M; Cotton FI; | 34563682 ENCS |
| 11 | The BigBrainWarp toolbox for integration of BigBrain 3D histology with multimodal neuroimaging | Paquola C; Royer J; Lewis LB; Lepage C; Glatard T; Wagstyl K; DeKraker J; Toussaint PJ; Valk SL; Collins DL; Khan A; Amunts K; Evans AC; Dickscheid T; Bernhardt BC; | 34431476 IMAGING |
| 12 | An analysis of security vulnerabilities in container images for scientific data analysis | Kaur B; Dugré M; Hanna A; Glatard T; | 34080631 ENCS |
| 13 | File-based localization of numerical perturbations in data analysis pipelines. | Salari A, Kiar G, Lewis L, Evans AC, Glatard T | 33269388 ENCS |
| 14 | A Benchmark of Data Stream Classification for Human Activity Recognition on Connected Objects. | Khannouz M; Glatard T; | 33202905 ENCS |
| 15 | Comparing perturbation models for evaluating stability of neuroimaging pipelines. | Kiar G, de Oliveira Castro P, Rioux P, Petit E, Brown ST, Evans AC, Glatard T | 32831546 IMAGING |
| 16 | A Quantitative Comparison of Overlapping and Non-Overlapping Sliding Windows for Human Activity Recognition Using Inertial Sensors. | Dehghani A, Sarbishei O, Glatard T, Shihab E | 31752158 ENCS |
| 17 | Cyberinfrastructure for Open Science at the Montreal Neurological Institute. | Das S, Glatard T, Rogers C, Saigle J, Paiva S, MacIntyre L, Safi-Harab M, Rousseau ME, Stirling J, Khalili-Mahani N, MacFarlane D, Kostopoulos P, Rioux P, Madjar C, Lecours-Boucher X, Vanamala S, Adalat R, Mohaddes Z, Fonov VS, Milot S, Leppert I, Degroot C, Durcan TM, Campbell T, Moreau J, Dagher A, Collins DL, Karamchandani J, Bar-Or A, Fon EA, Hoge R, Baillet S, Rouleau G, Evans AC | 28111547 IMAGING |
| 18 | Best practices in data analysis and sharing in neuroimaging using MRI. | Nichols TE, Das S, Eickhoff SB, Evans AC, Glatard T, Hanke M, Kriegeskorte N, Milham MP, Poldrack RA, Poline JB, Proal E, Thirion B, Van Essen DC, White T, Yeo BT | 28230846 IMAGING |
| 19 | The first MICCAI challenge on PET tumor segmentation. | Hatt M, Laurent B, Ouahabi A, Fayad H, Tan S, Li L, Lu W, Jaouen V, Tauber C, Czakon J, Drapejkowski F, Dyrka W, Camarasu-Pop S, Cervenansky F, Girard P, Glatard T, Kain M, Yao Y, Barillot C, Kirov A, Visvikis D | 29268169 IMAGING |
| 20 | Boutiques: a flexible framework to integrate command-line applications in computing platforms. | Glatard T, Kiar G, Aumentado-Armstrong T, Beck N, Bellec P, Bernard R, Bonnet A, Brown ST, Camarasu-Pop S, Cervenansky F, Das S, Ferreira da Silva R, Flandin G, Girard P, Gorgolewski KJ, Guttmann CRG, Hayot-Sasson V, Quirion PO, Rioux P, Rousseau MÉ, Evans AC | 29718199 ENCS |
| 21 | Objective Evaluation of Multiple Sclerosis Lesion Segmentation using a Data Management and Processing Infrastructure. | Commowick O, Istace A, Kain M, Laurent B, Leray F, Simon M, Pop SC, Girard P, Améli R, Ferré JC, Kerbrat A, Tourdias T, Cervenansky F, Glatard T, Beaumont J, Doyle S, Forbes F, Knight J, Khademi A, Mahbod A, Wang C, McKinley R, Wagner F, Muschelli J, Sweeney E, Roura E, Lladó X, Santos MM, Santos WP, Silva-Filho AG, Tomas-Fernandez X, Urien H, Bloch I, Valverde S, Cabezas M, Vera-Olmos FJ, Malpica N, Guttmann C, Vukusic S, Edan G, Dojat M, Styner M, Warfield SK, Cotton F, Barillot C | 30209345 ENCS |
| 22 | A Serverless Tool for Platform Agnostic Computational Experiment Management. | Kiar G, Brown ST, Glatard T, Evans AC | 30890927 ENCS |
| Title: | Predicting Parkinson's disease trajectory using clinical and functional MRI features: A reproduction and replication study | ||||
| Authors: | Germani E, Bhagwat N, Dugré M, Gau R, Montillo AA, Nguyen KP, Sokolowski A, Sharp M, Poline JB, Glatard T | ||||
| Link: | https://pubmed.ncbi.nlm.nih.gov/39982930/ | ||||
| DOI: | 10.1371/journal.pone.0317566 | ||||
| Publication: | PloS one | ||||
| Keywords: | |||||
| PMID: | 39982930 | Category: | Date Added: | 2025-02-21 | |
| Dept Affiliation: |
ENCS
1 Univ Rennes, Inria, CNRS, Inserm, Rennes, France. 2 Department of Neurology and Neurosurgery, McGill University, Montreal, Canada. 3 Department of Computer Science and Software Engineering, Concordia University, Montreal, Canada. 4 Lyda Hill Department of Bioinformatics, University of Texas Southwestern Medical Center, Dallas, TX, United States of America. |
||||
Description: |
Parkinson's disease (PD) is a common neurodegenerative disorder with a poorly understood physiopathology and no established biomarkers for the diagnosis of early stages and for prediction of disease progression. Several neuroimaging biomarkers have been studied recently, but these are susceptible to several sources of variability related for instance to cohort selection or image analysis. In this context, an evaluation of the robustness of such biomarkers to variations in the data processing workflow is essential. This study is part of a larger project investigating the replicability of potential neuroimaging biomarkers of PD. Here, we attempt to fully reproduce (reimplementing the experiments with the same methods, including data collection from the same database) and replicate (different data and/or method) the models described in (Nguyen et al., 2021) to predict individual's PD current state and progression using demographic, clinical and neuroimaging features (fALFF and ReHo extracted from resting-state fMRI). We use the Parkinson's Progression Markers Initiative dataset (PPMI, ppmi-info.org), as in (Nguyen et al., 2021) and aim to reproduce the original cohort, imaging features and machine learning models as closely as possible using the information available in the paper and the code. We also investigated methodological variations in cohort selection, feature extraction pipelines and sets of input features. Different criteria were used to evaluate the reproduction attempt and compare the results with the original ones. Notably, we obtained significantly better than chance performance using the analysis pipeline closest to that in the original study (R2 > 0), which is consistent with its findings. In addition, we performed a partial reproduction using derived data provided by the authors of the original study, and we obtained results that were close to the original ones. The challenges encountered while attempting to reproduce (fully and partially) and replicating the original work are likely explained by the complexity of neuroimaging studies, in particular in clinical settings. We provide recommendations to further facilitate the reproducibility of such studies in the future. |
