A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients

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A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients. / Ladefoged, Claes Nøhr; Law, Ian; Anazodo, Udunna; St. Lawrence, Keith; Izquierdo-Garcia, David; Catana, Ciprian; Burgos, Ninon; Cardoso, Manuel Jorge; Ourselin, Sebastien; Hutton, Brian; Mérida, Inés; Costes, Nicolas; Hammers, Alexander; Benoit, Didier; Holm, Søren; Juttukonda, Meher; An, Hongyu; Cabello, Jorge; Lukas, Mathias; Nekolla, Stephan; Ziegler, Sibylle; Fenchel, Matthias; Jakoby, Björn; Casey, Michael E.; Benzinger, Tammie; Højgaard, Liselotte; Hansen, Adam E.; Andersen, Flemming L.

I: NeuroImage, Bind 147, 15.02.2017, s. 346-359.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Ladefoged, CN, Law, I, Anazodo, U, St. Lawrence, K, Izquierdo-Garcia, D, Catana, C, Burgos, N, Cardoso, MJ, Ourselin, S, Hutton, B, Mérida, I, Costes, N, Hammers, A, Benoit, D, Holm, S, Juttukonda, M, An, H, Cabello, J, Lukas, M, Nekolla, S, Ziegler, S, Fenchel, M, Jakoby, B, Casey, ME, Benzinger, T, Højgaard, L, Hansen, AE & Andersen, FL 2017, 'A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients', NeuroImage, bind 147, s. 346-359. https://doi.org/10.1016/j.neuroimage.2016.12.010

APA

Ladefoged, C. N., Law, I., Anazodo, U., St. Lawrence, K., Izquierdo-Garcia, D., Catana, C., Burgos, N., Cardoso, M. J., Ourselin, S., Hutton, B., Mérida, I., Costes, N., Hammers, A., Benoit, D., Holm, S., Juttukonda, M., An, H., Cabello, J., Lukas, M., ... Andersen, F. L. (2017). A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients. NeuroImage, 147, 346-359. https://doi.org/10.1016/j.neuroimage.2016.12.010

Vancouver

Ladefoged CN, Law I, Anazodo U, St. Lawrence K, Izquierdo-Garcia D, Catana C o.a. A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients. NeuroImage. 2017 feb. 15;147:346-359. https://doi.org/10.1016/j.neuroimage.2016.12.010

Author

Ladefoged, Claes Nøhr ; Law, Ian ; Anazodo, Udunna ; St. Lawrence, Keith ; Izquierdo-Garcia, David ; Catana, Ciprian ; Burgos, Ninon ; Cardoso, Manuel Jorge ; Ourselin, Sebastien ; Hutton, Brian ; Mérida, Inés ; Costes, Nicolas ; Hammers, Alexander ; Benoit, Didier ; Holm, Søren ; Juttukonda, Meher ; An, Hongyu ; Cabello, Jorge ; Lukas, Mathias ; Nekolla, Stephan ; Ziegler, Sibylle ; Fenchel, Matthias ; Jakoby, Björn ; Casey, Michael E. ; Benzinger, Tammie ; Højgaard, Liselotte ; Hansen, Adam E. ; Andersen, Flemming L. / A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients. I: NeuroImage. 2017 ; Bind 147. s. 346-359.

Bibtex

@article{d4991d3db2f24247be4cbd157f808e7b,
title = "A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients",
abstract = "Aim: To accurately quantify the radioactivity concentration measured by PET, emission data need to be corrected for photon attenuation; however, the MRI signal cannot easily be converted into attenuation values, making attenuation correction (AC) in PET/MRI challenging. In order to further improve the current vendor-implemented MR-AC methods for absolute quantification, a number of prototype methods have been proposed in the literature. These can be categorized into three types: template/atlas-based, segmentation-based, and reconstruction-based. These proposed methods in general demonstrated improvements compared to vendor-implemented AC, and many studies report deviations in PET uptake after AC of only a few percent from a gold standard CT-AC. Using a unified quantitative evaluation with identical metrics, subject cohort, and common CT-based reference, the aims of this study were to evaluate a selection of novel methods proposed in the literature, and identify the ones suitable for clinical use. Methods: In total, 11 AC methods were evaluated: two vendor-implemented (MR-ACDIXON and MR-ACUTE), five based on template/atlas information (MR-ACSEGBONE (Koesters et al., 2016), MR-ACONTARIO (Anazodo et al., 2014), MR-ACBOSTON (Izquierdo-Garcia et al., 2014), MR-ACUCL (Burgos et al., 2014), and MR-ACMAXPROB (Merida et al., 2015)), one based on simultaneous reconstruction of attenuation and emission (MR-ACMLAA (Benoit et al., 2015)), and three based on image-segmentation (MR-ACMUNICH (Cabello et al., 2015), MR-ACCAR-RiDR (Juttukonda et al., 2015), and MR-ACRESOLUTE (Ladefoged et al., 2015)). We selected 359 subjects who were scanned using one of the following radiotracers: [18F]FDG (210), [11C]PiB (51), and [18F]florbetapir (98). The comparison to AC with a gold standard CT was performed both globally and regionally, with a special focus on robustness and outlier analysis. Results: The average performance in PET tracer uptake was within ±5% of CT for all of the proposed methods, with the average±SD global percentage bias in PET FDG uptake for each method being: MR-ACDIXON (−11.3±3.5)%, MR-ACUTE (−5.7±2.0)%, MR-ACONTARIO (−4.3±3.6)%, MR-ACMUNICH (3.7±2.1)%, MR-ACMLAA (−1.9±2.6)%, MR-ACSEGBONE (−1.7±3.6)%, MR-ACUCL (0.8±1.2)%, MR-ACCAR-RiDR (−0.4±1.9)%, MR-ACMAXPROB (−0.4±1.6)%, MR-ACBOSTON (−0.3±1.8)%, and MR-ACRESOLUTE (0.3±1.7)%, ordered by average bias. The overall best performing methods (MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically) showed regional average errors within ±3% of PET with CT-AC in all regions of the brain with FDG, and the same four methods, as well as MR-ACCAR-RiDR, showed that for 95% of the patients, 95% of brain voxels had an uptake that deviated by less than 15% from the reference. Comparable performance was obtained with PiB and florbetapir. Conclusions: All of the proposed novel methods have an average global performance within likely acceptable limits (±5% of CT-based reference), and the main difference among the methods was found in the robustness, outlier analysis, and clinical feasibility. Overall, the best performing methods were MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically. These methods all minimized the number of outliers, standard deviation, and average global and local error. The methods MR-ACMUNICH and MR-ACCAR-RiDR were both within acceptable quantitative limits, so these methods should be considered if processing time is a factor. The method MR-ACSEGBONE also demonstrates promising results, and performs well within the likely acceptable quantitative limits. For clinical routine scans where processing time can be a key factor, this vendor-provided solution currently outperforms most methods. With the performance of the methods presented here, it may be concluded that the challenge of improving the accuracy of MR-AC in adult brains with normal anatomy has been solved to a quantitatively acceptable degree, which is smaller than the quantification reproducibility in PET imaging.",
keywords = "Attenuation correction, Brain, PET/MRI",
author = "Ladefoged, {Claes N{\o}hr} and Ian Law and Udunna Anazodo and {St. Lawrence}, Keith and David Izquierdo-Garcia and Ciprian Catana and Ninon Burgos and Cardoso, {Manuel Jorge} and Sebastien Ourselin and Brian Hutton and In{\'e}s M{\'e}rida and Nicolas Costes and Alexander Hammers and Didier Benoit and S{\o}ren Holm and Meher Juttukonda and Hongyu An and Jorge Cabello and Mathias Lukas and Stephan Nekolla and Sibylle Ziegler and Matthias Fenchel and Bj{\"o}rn Jakoby and Casey, {Michael E.} and Tammie Benzinger and Liselotte H{\o}jgaard and Hansen, {Adam E.} and Andersen, {Flemming L}",
year = "2017",
month = feb,
day = "15",
doi = "10.1016/j.neuroimage.2016.12.010",
language = "English",
volume = "147",
pages = "346--359",
journal = "NeuroImage",
issn = "1053-8119",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - A multi-centre evaluation of eleven clinically feasible brain PET/MRI attenuation correction techniques using a large cohort of patients

AU - Ladefoged, Claes Nøhr

AU - Law, Ian

AU - Anazodo, Udunna

AU - St. Lawrence, Keith

AU - Izquierdo-Garcia, David

AU - Catana, Ciprian

AU - Burgos, Ninon

AU - Cardoso, Manuel Jorge

AU - Ourselin, Sebastien

AU - Hutton, Brian

AU - Mérida, Inés

AU - Costes, Nicolas

AU - Hammers, Alexander

AU - Benoit, Didier

AU - Holm, Søren

AU - Juttukonda, Meher

AU - An, Hongyu

AU - Cabello, Jorge

AU - Lukas, Mathias

AU - Nekolla, Stephan

AU - Ziegler, Sibylle

AU - Fenchel, Matthias

AU - Jakoby, Björn

AU - Casey, Michael E.

AU - Benzinger, Tammie

AU - Højgaard, Liselotte

AU - Hansen, Adam E.

AU - Andersen, Flemming L

PY - 2017/2/15

Y1 - 2017/2/15

N2 - Aim: To accurately quantify the radioactivity concentration measured by PET, emission data need to be corrected for photon attenuation; however, the MRI signal cannot easily be converted into attenuation values, making attenuation correction (AC) in PET/MRI challenging. In order to further improve the current vendor-implemented MR-AC methods for absolute quantification, a number of prototype methods have been proposed in the literature. These can be categorized into three types: template/atlas-based, segmentation-based, and reconstruction-based. These proposed methods in general demonstrated improvements compared to vendor-implemented AC, and many studies report deviations in PET uptake after AC of only a few percent from a gold standard CT-AC. Using a unified quantitative evaluation with identical metrics, subject cohort, and common CT-based reference, the aims of this study were to evaluate a selection of novel methods proposed in the literature, and identify the ones suitable for clinical use. Methods: In total, 11 AC methods were evaluated: two vendor-implemented (MR-ACDIXON and MR-ACUTE), five based on template/atlas information (MR-ACSEGBONE (Koesters et al., 2016), MR-ACONTARIO (Anazodo et al., 2014), MR-ACBOSTON (Izquierdo-Garcia et al., 2014), MR-ACUCL (Burgos et al., 2014), and MR-ACMAXPROB (Merida et al., 2015)), one based on simultaneous reconstruction of attenuation and emission (MR-ACMLAA (Benoit et al., 2015)), and three based on image-segmentation (MR-ACMUNICH (Cabello et al., 2015), MR-ACCAR-RiDR (Juttukonda et al., 2015), and MR-ACRESOLUTE (Ladefoged et al., 2015)). We selected 359 subjects who were scanned using one of the following radiotracers: [18F]FDG (210), [11C]PiB (51), and [18F]florbetapir (98). The comparison to AC with a gold standard CT was performed both globally and regionally, with a special focus on robustness and outlier analysis. Results: The average performance in PET tracer uptake was within ±5% of CT for all of the proposed methods, with the average±SD global percentage bias in PET FDG uptake for each method being: MR-ACDIXON (−11.3±3.5)%, MR-ACUTE (−5.7±2.0)%, MR-ACONTARIO (−4.3±3.6)%, MR-ACMUNICH (3.7±2.1)%, MR-ACMLAA (−1.9±2.6)%, MR-ACSEGBONE (−1.7±3.6)%, MR-ACUCL (0.8±1.2)%, MR-ACCAR-RiDR (−0.4±1.9)%, MR-ACMAXPROB (−0.4±1.6)%, MR-ACBOSTON (−0.3±1.8)%, and MR-ACRESOLUTE (0.3±1.7)%, ordered by average bias. The overall best performing methods (MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically) showed regional average errors within ±3% of PET with CT-AC in all regions of the brain with FDG, and the same four methods, as well as MR-ACCAR-RiDR, showed that for 95% of the patients, 95% of brain voxels had an uptake that deviated by less than 15% from the reference. Comparable performance was obtained with PiB and florbetapir. Conclusions: All of the proposed novel methods have an average global performance within likely acceptable limits (±5% of CT-based reference), and the main difference among the methods was found in the robustness, outlier analysis, and clinical feasibility. Overall, the best performing methods were MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically. These methods all minimized the number of outliers, standard deviation, and average global and local error. The methods MR-ACMUNICH and MR-ACCAR-RiDR were both within acceptable quantitative limits, so these methods should be considered if processing time is a factor. The method MR-ACSEGBONE also demonstrates promising results, and performs well within the likely acceptable quantitative limits. For clinical routine scans where processing time can be a key factor, this vendor-provided solution currently outperforms most methods. With the performance of the methods presented here, it may be concluded that the challenge of improving the accuracy of MR-AC in adult brains with normal anatomy has been solved to a quantitatively acceptable degree, which is smaller than the quantification reproducibility in PET imaging.

AB - Aim: To accurately quantify the radioactivity concentration measured by PET, emission data need to be corrected for photon attenuation; however, the MRI signal cannot easily be converted into attenuation values, making attenuation correction (AC) in PET/MRI challenging. In order to further improve the current vendor-implemented MR-AC methods for absolute quantification, a number of prototype methods have been proposed in the literature. These can be categorized into three types: template/atlas-based, segmentation-based, and reconstruction-based. These proposed methods in general demonstrated improvements compared to vendor-implemented AC, and many studies report deviations in PET uptake after AC of only a few percent from a gold standard CT-AC. Using a unified quantitative evaluation with identical metrics, subject cohort, and common CT-based reference, the aims of this study were to evaluate a selection of novel methods proposed in the literature, and identify the ones suitable for clinical use. Methods: In total, 11 AC methods were evaluated: two vendor-implemented (MR-ACDIXON and MR-ACUTE), five based on template/atlas information (MR-ACSEGBONE (Koesters et al., 2016), MR-ACONTARIO (Anazodo et al., 2014), MR-ACBOSTON (Izquierdo-Garcia et al., 2014), MR-ACUCL (Burgos et al., 2014), and MR-ACMAXPROB (Merida et al., 2015)), one based on simultaneous reconstruction of attenuation and emission (MR-ACMLAA (Benoit et al., 2015)), and three based on image-segmentation (MR-ACMUNICH (Cabello et al., 2015), MR-ACCAR-RiDR (Juttukonda et al., 2015), and MR-ACRESOLUTE (Ladefoged et al., 2015)). We selected 359 subjects who were scanned using one of the following radiotracers: [18F]FDG (210), [11C]PiB (51), and [18F]florbetapir (98). The comparison to AC with a gold standard CT was performed both globally and regionally, with a special focus on robustness and outlier analysis. Results: The average performance in PET tracer uptake was within ±5% of CT for all of the proposed methods, with the average±SD global percentage bias in PET FDG uptake for each method being: MR-ACDIXON (−11.3±3.5)%, MR-ACUTE (−5.7±2.0)%, MR-ACONTARIO (−4.3±3.6)%, MR-ACMUNICH (3.7±2.1)%, MR-ACMLAA (−1.9±2.6)%, MR-ACSEGBONE (−1.7±3.6)%, MR-ACUCL (0.8±1.2)%, MR-ACCAR-RiDR (−0.4±1.9)%, MR-ACMAXPROB (−0.4±1.6)%, MR-ACBOSTON (−0.3±1.8)%, and MR-ACRESOLUTE (0.3±1.7)%, ordered by average bias. The overall best performing methods (MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically) showed regional average errors within ±3% of PET with CT-AC in all regions of the brain with FDG, and the same four methods, as well as MR-ACCAR-RiDR, showed that for 95% of the patients, 95% of brain voxels had an uptake that deviated by less than 15% from the reference. Comparable performance was obtained with PiB and florbetapir. Conclusions: All of the proposed novel methods have an average global performance within likely acceptable limits (±5% of CT-based reference), and the main difference among the methods was found in the robustness, outlier analysis, and clinical feasibility. Overall, the best performing methods were MR-ACBOSTON, MR-ACMAXPROB, MR-ACRESOLUTE and MR-ACUCL, ordered alphabetically. These methods all minimized the number of outliers, standard deviation, and average global and local error. The methods MR-ACMUNICH and MR-ACCAR-RiDR were both within acceptable quantitative limits, so these methods should be considered if processing time is a factor. The method MR-ACSEGBONE also demonstrates promising results, and performs well within the likely acceptable quantitative limits. For clinical routine scans where processing time can be a key factor, this vendor-provided solution currently outperforms most methods. With the performance of the methods presented here, it may be concluded that the challenge of improving the accuracy of MR-AC in adult brains with normal anatomy has been solved to a quantitatively acceptable degree, which is smaller than the quantification reproducibility in PET imaging.

KW - Attenuation correction

KW - Brain

KW - PET/MRI

U2 - 10.1016/j.neuroimage.2016.12.010

DO - 10.1016/j.neuroimage.2016.12.010

M3 - Journal article

C2 - 27988322

AN - SCOPUS:85007086820

VL - 147

SP - 346

EP - 359

JO - NeuroImage

JF - NeuroImage

SN - 1053-8119

ER -

ID: 180826060