BISON: Brain tISue segmentatiON pipeline using T1-weighted magnetic resonance images and a random forests classifier

Dadar, Mahsa; Collins, D. Louis

doi:10.1101/747998

Cited by 8 publications

(17 citation statements)

References 44 publications

(38 reference statements)

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“…All pipelines used in the processing of the images have been developed and validated for use in multi-center and multi-scanner datasets and have been previously used in many such applications. 19,18,24…”

Section: Methodsmentioning

confidence: 99%

Conversion of diffusely abnormal white matter to focal lesions is linked to progression in secondary progressive multiple sclerosis

et al. 2020

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Background: Diffusely abnormal white matter (DAWM) regions are observed in magnetic resonance images of secondary progressive multiple sclerosis (SPMS) patients. However, their role in clinical progression is still not established. Objectives: To characterize the longitudinal volumetric and intensity evolution of DAWM and focal white matter lesions (FWML) and assess their associations with clinical outcomes and progression in SPMS. Methods: Data include 589 SPMS participants followed up for 3 years (3951 time points). FWML and DAWM were automatically segmented. Screening DAWM volumes that transformed into FWML at the last visit (DAWM-to-FWML) and normalized T1-weighted intensities (indicating severity of damage) in those voxels were calculated. Results: FWML volume increased and DAWM volume decreased with an increase in disease duration ( p < 0.001). The Expanded Disability Status Scale (EDSS) was positively associated with FWML volumes ( p = 0.002), but not with DAWM. DAWM-to-FWML volume was higher in patients who progressed (2.75 cm3 vs. 1.70 cm3; p < 0.0001). Normalized T1-weighted intensity of DAWM-to-FWML was negatively associated with progression ( p < 0.00001). Conclusion: DAWM transformed into FWML over time, and this transformation was associated with clinical progression. DAWM-to-FWML voxels had greater normalized T1-weighted intensity decrease over time, in keeping with relatively greater tissue damage. Evaluation of DAWM in progressive multiple sclerosis provides a useful measure for therapies aiming to protect this at-risk tissue with the potential to slow progression.

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Section: Methodsmentioning

confidence: 99%

Conversion of diffusely abnormal white matter to focal lesions is linked to progression in secondary progressive multiple sclerosis

et al. 2020

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“…All scans were processed using our standard image processing pipeline for longitudinal data, extensively described in our previous work 10,12 . Briefly, the steps applied to the MRI data at each timepoint are: 1) Intensity non-uniformity correction 14 ; 2) linear intensity normalization; 3) brain tissue extraction 15 ; 4) tissue classification using T1w images 16 ; 5) rigid co-registration of T2w to T1w images; 6) linear and nonlinear registration of the T1w images to MNI-ICBM152-2009c template 17,18 ; 7) automatic segmentation of WM lesions using a Bayesian Classifier, used to mask lesion voxels and obtain the intensity mode of the NAWM voxels 19 ; 8) automatic separation of FWML from DAWM using intensity thresholds based on normalized T2 intensity mode values (the details of this automated separation techniques have been described in our previous studies) 10,12 .…”

Section: Image Processingmentioning

confidence: 99%

Diffusely abnormal white matter converts to T2 lesion volume in the absence of acute inflammation

Dadar

Mahmoud

Narayanan

et al. 2021

Preprint

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Diffusely abnormal white matter (DAWM), characterised by biochemical changes of myelin in the absence of frank demyelination, has been associated with clinical progression in secondary progressive MS (SPMS). However, little is known about changes of DAWM over time and their relation to focal white matter lesions (FWML). The objectives of this work were: 1) To characterize the longitudinal evolution of FWML, DAWM, and DAWM that transforms into FWML, and 2) To determine whether gadolinium enhancement, known to be associated with the development of new FWML, is also related to DAWM voxels that transform into FWML. Our data included 4220 MRI scans of 689 SPMS participants, followed for 156 weeks and 2677 scans of 686 RRMS participants, followed for 96 weeks. FWML and DAWM were segmented using a previously validated, automatic thresholding technique based on normalized T2 intensity values. Using longitudinally registered images, DAWM voxels at each visit that transformed into FWML on the last MRI scan as well as their overlap with gadolinium enhancing lesion masks were identified. Our results showed that the average yearly rate of conversion of DAWM-to-FWML was 1.27cc for SPMS and 0.80cc for RRMS. FWML in SPMS participants significantly increased (t=3.9; p=0.0001) while DAWM significantly decreased (t=-4.3 p<0.0001) and the ratio FWML:DAWM increased (t=12.7; p<0.00001). RRMS participants also showed an increase in the FWML:DAWM Ratio (t=6.9; p<0.00001) but without a significant change of the individual volumes. Gadolinium enhancement was associated with 7.3% and 18.7% of focal New T2 lesion formation in the infrequent scans of the RRMS and SPMS cohorts, respectively. In comparison, only 0.1% and 0.0% of DAWM-to-FWML voxels overlapped with gadolinium enhancement. We conclude that DAWM transforms into FWML over time, in both RRMS and SPMS. DAWM appears to represent a form of pre-lesional pathology that contributes to T2 lesion volume increase over time, independent of new focal inflammation and gadolinium enhancement.

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“…Tissue segmentations were performed after these preprocessing steps using: 1) Atropos (Avants et al, 2011); 2) BISON (Dadar and Collins, 2019); 3) Classify_Clean (Cocosco et al, 2003); FAST 5.0 (Zhang et al, 2001); FreeSurfer 6.0.0 (Fischl, 2012); and SPM12 (Penny et al, 2011). For all pipelines, default settings were used.…”

Section: Tissue Segmentationmentioning

confidence: 99%

“…Brain tISue segmentatiON (BISON) is an open source pipeline based on a random forests classifier that has been trained using a set of intensity and location features from a multi-center manually labelled dataset of 72 individuals aged from 5-96 years (Dadar and Collins, 2019). The BISON script as well as a pretrained random forest classifier is publicly available at http://nist.mni.mcgill.ca/?p=2148.…”

Section: Bisonmentioning

confidence: 99%

“…Using data from the Single Individual volunteer for Multiple Observations across Networks (SIMON) public dataset, we had a unique opportunity to perform such comparison across 90 scans of this single individual, acquired within the span of seven years on 28 different sites with 12 different scanner models. In this study, we compared the performance of six publicly available, widely used tissue classification methods (Atropos (Avants et al, 2011); BISON (Dadar and Collins, 2019); Classify_Clean (Cocosco et al, 2003); FAST (Zhang et al, 2001); FreeSurfer (Fischl, 2012); and SPM12 (Ashburner et al, 2014, p. 12). These comparisons provide a benchmark on the reliability of each technique, and the amount of variability that can be expected when using multi-center datasets.…”

Section: Introductionmentioning

confidence: 99%

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Reliability Assessment of Tissue Classification Algorithms for Multi-Center and Multi-Scanner Data

Dadar

Duchesne

2020

Preprint

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AbstractBackgroundGray and white matter volume difference and change are important imaging markers of pathology and disease progression in neurology and psychiatry. Such measures are usually estimated from tissue segmentation maps produced by publicly available image processing pipelines. However, the reliability of the produced segmentations when using multi-center and multi-scanner data remains understudied. Here, we assess the robustness of six publicly available tissue classification pipelines across images acquired from different MR scanners and sites.MethodsWe used T1-weighted images of a single individual, scanned in 73 sessions across 27 different sites to assess the robustness of the tissue classification tools. Variability in Dice Kappa values and tissue volumes was assessed for Atropos, BISON, Classify_Clean, FAST, FreeSurfer, and SPM12. We also estimated the sample size necessary to detect a significant 1% volume reduction based on the variability of the estimates from each method within and across scanner models.ResultsBISON had the lowest overall variability in its volumetric estimates, followed by FreeSurfer, and SPM12. All methods also had significant differences between some of their estimates across different scanner manufacturers (e.g. BISON had significantly higher GM estimates and correspondingly lower WM estimates for GE scans compared to Philips and SIEMENs), and different signal-to-noise ratio (SNR) levels (e.g. FAST and FreeSurfer had significantly higher WM volume estimates for high versus medium and low SNR tertiles as well as correspondingly lower GM volume estimates). BISON also had the smallest sample size requirement across all scanners and tissue types, followed by FreeSurfer, and SPM12.ConclusionsOur comparisons provide a benchmark on the reliability of the publicly used tissue classification techniques and the amount of variability that can be expected when using large multi-center datasets and multi-scanner databases.

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BISON: Brain tISue segmentatiON pipeline using T1-weighted magnetic resonance images and a random forests classifier

Cited by 8 publications

References 44 publications

Conversion of diffusely abnormal white matter to focal lesions is linked to progression in secondary progressive multiple sclerosis

Conversion of diffusely abnormal white matter to focal lesions is linked to progression in secondary progressive multiple sclerosis

Diffusely abnormal white matter converts to T2 lesion volume in the absence of acute inflammation

Reliability Assessment of Tissue Classification Algorithms for Multi-Center and Multi-Scanner Data

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