Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study

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Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study. / de Sitter, Alexandra; Steenwijk, Martijn D; Ruet, Aurélie; Versteeg, Adriaan; Liu, Yaou; van Schijndel, Ronald A; Pouwels, Petra J W; Kilsdonk, Iris D; Cover, Keith S; van Dijk, Bob W; Ropele, Stefan; Rocca, Maria A; Yiannakas, Marios; Wattjes, Mike P; Damangir, Soheil; Frisoni, Giovanni B; Sastre-Garriga, Jaume; Rovira, Alex; Enzinger, Christian; Filippi, Massimo; Frederiksen, Jette; Ciccarelli, Olga; Kappos, Ludwig; Barkhof, Frederik; Vrenken, Hugo; MAGNIMS study group and for neuGRID.

I: NeuroImage, Bind 163, 2017, s. 106-114.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

de Sitter, A, Steenwijk, MD, Ruet, A, Versteeg, A, Liu, Y, van Schijndel, RA, Pouwels, PJW, Kilsdonk, ID, Cover, KS, van Dijk, BW, Ropele, S, Rocca, MA, Yiannakas, M, Wattjes, MP, Damangir, S, Frisoni, GB, Sastre-Garriga, J, Rovira, A, Enzinger, C, Filippi, M, Frederiksen, J, Ciccarelli, O, Kappos, L, Barkhof, F, Vrenken, H & MAGNIMS study group and for neuGRID 2017, 'Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study', NeuroImage, bind 163, s. 106-114. https://doi.org/10.1016/j.neuroimage.2017.09.011

APA

de Sitter, A., Steenwijk, M. D., Ruet, A., Versteeg, A., Liu, Y., van Schijndel, R. A., Pouwels, P. J. W., Kilsdonk, I. D., Cover, K. S., van Dijk, B. W., Ropele, S., Rocca, M. A., Yiannakas, M., Wattjes, M. P., Damangir, S., Frisoni, G. B., Sastre-Garriga, J., Rovira, A., Enzinger, C., ... MAGNIMS study group and for neuGRID (2017). Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study. NeuroImage, 163, 106-114. https://doi.org/10.1016/j.neuroimage.2017.09.011

Vancouver

de Sitter A, Steenwijk MD, Ruet A, Versteeg A, Liu Y, van Schijndel RA o.a. Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study. NeuroImage. 2017;163:106-114. https://doi.org/10.1016/j.neuroimage.2017.09.011

Author

de Sitter, Alexandra ; Steenwijk, Martijn D ; Ruet, Aurélie ; Versteeg, Adriaan ; Liu, Yaou ; van Schijndel, Ronald A ; Pouwels, Petra J W ; Kilsdonk, Iris D ; Cover, Keith S ; van Dijk, Bob W ; Ropele, Stefan ; Rocca, Maria A ; Yiannakas, Marios ; Wattjes, Mike P ; Damangir, Soheil ; Frisoni, Giovanni B ; Sastre-Garriga, Jaume ; Rovira, Alex ; Enzinger, Christian ; Filippi, Massimo ; Frederiksen, Jette ; Ciccarelli, Olga ; Kappos, Ludwig ; Barkhof, Frederik ; Vrenken, Hugo ; MAGNIMS study group and for neuGRID. / Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study. I: NeuroImage. 2017 ; Bind 163. s. 106-114.

Bibtex

@article{7dc68ec45d944e4d9e2cd3795a3b1dc6,
title = "Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study",
abstract = "BACKGROUND AND PURPOSE: In vivoidentification of white matter lesions plays a key-role in evaluation of patients with multiple sclerosis (MS). Automated lesion segmentation methods have been developed to substitute manual outlining, but evidence of their performance in multi-center investigations is lacking. In this work, five research-domain automated segmentation methods were evaluated using a multi-center MS dataset.METHODS: 70 MS patients (median EDSS of 2.0 [range 0.0-6.5]) were included from a six-center dataset of the MAGNIMS Study Group (www.magnims.eu) which included 2D FLAIR and 3D T1 images with manual lesion segmentation as a reference. Automated lesion segmentations were produced using five algorithms: Cascade; Lesion Segmentation Toolbox (LST) with both the Lesion growth algorithm (LGA) and the Lesion prediction algorithm (LPA); Lesion-Topology preserving Anatomical Segmentation (Lesion-TOADS); and k-Nearest Neighbor with Tissue Type Priors (kNN-TTP). Main software parameters were optimized using a training set (N = 18), and formal testing was performed on the remaining patients (N = 52). To evaluate volumetric agreement with the reference segmentations, intraclass correlation coefficient (ICC) as well as mean difference in lesion volumes between the automated and reference segmentations were calculated. The Similarity Index (SI), False Positive (FP) volumes and False Negative (FN) volumes were used to examine spatial agreement. All analyses were repeated using a leave-one-center-out design to exclude the center of interest from the training phase to evaluate the performance of the method on 'unseen' center.RESULTS: Compared to the reference mean lesion volume (4.85 ± 7.29 mL), the methods displayed a mean difference of 1.60 ± 4.83 (Cascade), 2.31 ± 7.66 (LGA), 0.44 ± 4.68 (LPA), 1.76 ± 4.17 (Lesion-TOADS) and -1.39 ± 4.10 mL (kNN-TTP). The ICCs were 0.755, 0.713, 0.851, 0.806 and 0.723, respectively. Spatial agreement with reference segmentations was higher for LPA (SI = 0.37 ± 0.23), Lesion-TOADS (SI = 0.35 ± 0.18) and kNN-TTP (SI = 0.44 ± 0.14) than for Cascade (SI = 0.26 ± 0.17) or LGA (SI = 0.31 ± 0.23). All methods showed highly similar results when used on data from a center not used in software parameter optimization.CONCLUSION: The performance of the methods in this multi-center MS dataset was moderate, but appeared to be robust even with new datasets from centers not included in training the automated methods.",
author = "{de Sitter}, Alexandra and Steenwijk, {Martijn D} and Aur{\'e}lie Ruet and Adriaan Versteeg and Yaou Liu and {van Schijndel}, {Ronald A} and Pouwels, {Petra J W} and Kilsdonk, {Iris D} and Cover, {Keith S} and {van Dijk}, {Bob W} and Stefan Ropele and Rocca, {Maria A} and Marios Yiannakas and Wattjes, {Mike P} and Soheil Damangir and Frisoni, {Giovanni B} and Jaume Sastre-Garriga and Alex Rovira and Christian Enzinger and Massimo Filippi and Jette Frederiksen and Olga Ciccarelli and Ludwig Kappos and Frederik Barkhof and Hugo Vrenken and {MAGNIMS study group and for neuGRID}",
note = "Copyright {\textcopyright} 2017 Elsevier Inc. All rights reserved.",
year = "2017",
doi = "10.1016/j.neuroimage.2017.09.011",
language = "English",
volume = "163",
pages = "106--114",
journal = "NeuroImage",
issn = "1053-8119",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Performance of five research-domain automated WM lesion segmentation methods in a multi-center MS study

AU - de Sitter, Alexandra

AU - Steenwijk, Martijn D

AU - Ruet, Aurélie

AU - Versteeg, Adriaan

AU - Liu, Yaou

AU - van Schijndel, Ronald A

AU - Pouwels, Petra J W

AU - Kilsdonk, Iris D

AU - Cover, Keith S

AU - van Dijk, Bob W

AU - Ropele, Stefan

AU - Rocca, Maria A

AU - Yiannakas, Marios

AU - Wattjes, Mike P

AU - Damangir, Soheil

AU - Frisoni, Giovanni B

AU - Sastre-Garriga, Jaume

AU - Rovira, Alex

AU - Enzinger, Christian

AU - Filippi, Massimo

AU - Frederiksen, Jette

AU - Ciccarelli, Olga

AU - Kappos, Ludwig

AU - Barkhof, Frederik

AU - Vrenken, Hugo

AU - MAGNIMS study group and for neuGRID

N1 - Copyright © 2017 Elsevier Inc. All rights reserved.

PY - 2017

Y1 - 2017

N2 - BACKGROUND AND PURPOSE: In vivoidentification of white matter lesions plays a key-role in evaluation of patients with multiple sclerosis (MS). Automated lesion segmentation methods have been developed to substitute manual outlining, but evidence of their performance in multi-center investigations is lacking. In this work, five research-domain automated segmentation methods were evaluated using a multi-center MS dataset.METHODS: 70 MS patients (median EDSS of 2.0 [range 0.0-6.5]) were included from a six-center dataset of the MAGNIMS Study Group (www.magnims.eu) which included 2D FLAIR and 3D T1 images with manual lesion segmentation as a reference. Automated lesion segmentations were produced using five algorithms: Cascade; Lesion Segmentation Toolbox (LST) with both the Lesion growth algorithm (LGA) and the Lesion prediction algorithm (LPA); Lesion-Topology preserving Anatomical Segmentation (Lesion-TOADS); and k-Nearest Neighbor with Tissue Type Priors (kNN-TTP). Main software parameters were optimized using a training set (N = 18), and formal testing was performed on the remaining patients (N = 52). To evaluate volumetric agreement with the reference segmentations, intraclass correlation coefficient (ICC) as well as mean difference in lesion volumes between the automated and reference segmentations were calculated. The Similarity Index (SI), False Positive (FP) volumes and False Negative (FN) volumes were used to examine spatial agreement. All analyses were repeated using a leave-one-center-out design to exclude the center of interest from the training phase to evaluate the performance of the method on 'unseen' center.RESULTS: Compared to the reference mean lesion volume (4.85 ± 7.29 mL), the methods displayed a mean difference of 1.60 ± 4.83 (Cascade), 2.31 ± 7.66 (LGA), 0.44 ± 4.68 (LPA), 1.76 ± 4.17 (Lesion-TOADS) and -1.39 ± 4.10 mL (kNN-TTP). The ICCs were 0.755, 0.713, 0.851, 0.806 and 0.723, respectively. Spatial agreement with reference segmentations was higher for LPA (SI = 0.37 ± 0.23), Lesion-TOADS (SI = 0.35 ± 0.18) and kNN-TTP (SI = 0.44 ± 0.14) than for Cascade (SI = 0.26 ± 0.17) or LGA (SI = 0.31 ± 0.23). All methods showed highly similar results when used on data from a center not used in software parameter optimization.CONCLUSION: The performance of the methods in this multi-center MS dataset was moderate, but appeared to be robust even with new datasets from centers not included in training the automated methods.

AB - BACKGROUND AND PURPOSE: In vivoidentification of white matter lesions plays a key-role in evaluation of patients with multiple sclerosis (MS). Automated lesion segmentation methods have been developed to substitute manual outlining, but evidence of their performance in multi-center investigations is lacking. In this work, five research-domain automated segmentation methods were evaluated using a multi-center MS dataset.METHODS: 70 MS patients (median EDSS of 2.0 [range 0.0-6.5]) were included from a six-center dataset of the MAGNIMS Study Group (www.magnims.eu) which included 2D FLAIR and 3D T1 images with manual lesion segmentation as a reference. Automated lesion segmentations were produced using five algorithms: Cascade; Lesion Segmentation Toolbox (LST) with both the Lesion growth algorithm (LGA) and the Lesion prediction algorithm (LPA); Lesion-Topology preserving Anatomical Segmentation (Lesion-TOADS); and k-Nearest Neighbor with Tissue Type Priors (kNN-TTP). Main software parameters were optimized using a training set (N = 18), and formal testing was performed on the remaining patients (N = 52). To evaluate volumetric agreement with the reference segmentations, intraclass correlation coefficient (ICC) as well as mean difference in lesion volumes between the automated and reference segmentations were calculated. The Similarity Index (SI), False Positive (FP) volumes and False Negative (FN) volumes were used to examine spatial agreement. All analyses were repeated using a leave-one-center-out design to exclude the center of interest from the training phase to evaluate the performance of the method on 'unseen' center.RESULTS: Compared to the reference mean lesion volume (4.85 ± 7.29 mL), the methods displayed a mean difference of 1.60 ± 4.83 (Cascade), 2.31 ± 7.66 (LGA), 0.44 ± 4.68 (LPA), 1.76 ± 4.17 (Lesion-TOADS) and -1.39 ± 4.10 mL (kNN-TTP). The ICCs were 0.755, 0.713, 0.851, 0.806 and 0.723, respectively. Spatial agreement with reference segmentations was higher for LPA (SI = 0.37 ± 0.23), Lesion-TOADS (SI = 0.35 ± 0.18) and kNN-TTP (SI = 0.44 ± 0.14) than for Cascade (SI = 0.26 ± 0.17) or LGA (SI = 0.31 ± 0.23). All methods showed highly similar results when used on data from a center not used in software parameter optimization.CONCLUSION: The performance of the methods in this multi-center MS dataset was moderate, but appeared to be robust even with new datasets from centers not included in training the automated methods.

U2 - 10.1016/j.neuroimage.2017.09.011

DO - 10.1016/j.neuroimage.2017.09.011

M3 - Journal article

C2 - 28899746

VL - 163

SP - 106

EP - 114

JO - NeuroImage

JF - NeuroImage

SN - 1053-8119

ER -

ID: 195009857