Big GABA: Edited MR spectroscopy at 24 research sites

Mark Mikkelsen; Peter B. Barker; Pallab K. Bhattacharyya; Maiken K. Brix; Pieter F. Buur; Kim M. Cecil; Kimberly L. Chan; David Y.T. Chen; Alexander R. Craven; Koen Cuypers; Michael Dacko; Niall W. Duncan; Ulrike Dydak; David A. Edmondson; Gabriele Ende; Lars Ersland; Fei Gao; Ian Greenhouse; Ashley D. Harris; Naying He; Stefanie Heba; Nigel Hoggard; Tun Wei Hsu; Jacobus F.A. Jansen; Alayar Kangarlu; Thomas Lange; R. Marc Lebel; Yan Li; Chien Yuan E. Lin; Jy Kang Liou; Jiing Feng Lirng; Feng Liu; Ruoyun Ma; Celine Maes; Marta Moreno-Ortega; Scott O. Murray; Sean Noah; Ralph Noeske; Michael D. Noseworthy; Georg Oeltzschner; James J. Prisciandaro; Nicolaas A.J. Puts; Timothy P.L. Roberts; Markus Sack; Napapon Sailasuta; Muhammad G. Saleh; Michael Paul Schallmo; Nicholas Simard; Stephan P. Swinnen; Martin Tegenthoff; Peter Truong; Guangbin Wang; Iain D. Wilkinson; Hans Jörg Wittsack; Hongmin Xu; Fuhua Yan; Chencheng Zhang; Vadim Zipunnikov; Helge J. Zöllner; Richard A.E. Edden

doi:10.1016/j.neuroimage.2017.07.021

Big GABA: Edited MR spectroscopy at 24 research sites

Mark Mikkelsen, Peter B. Barker, Pallab K. Bhattacharyya, Maiken K. Brix, Pieter F. Buur, Kim M. Cecil, Kimberly L. Chan, David Y.T. Chen, Alexander R. Craven, Koen Cuypers, Michael Dacko, Niall W. Duncan, Ulrike Dydak, David A. Edmondson, Gabriele Ende, Lars Ersland, Fei Gao, Ian Greenhouse, Ashley D. Harris, Naying HeStefanie Heba, Nigel Hoggard, Tun Wei Hsu, Jacobus F.A. Jansen, Alayar Kangarlu, Thomas Lange, R. Marc Lebel, Yan Li, Chien Yuan E. Lin, Jy Kang Liou, Jiing Feng Lirng, Feng Liu, Ruoyun Ma, Celine Maes, Marta Moreno-Ortega, Scott O. Murray, Sean Noah, Ralph Noeske, Michael D. Noseworthy, Georg Oeltzschner, James J. Prisciandaro, Nicolaas A.J. Puts, Timothy P.L. Roberts, Markus Sack, Napapon Sailasuta, Muhammad G. Saleh, Michael Paul Schallmo, Nicholas Simard, Stephan P. Swinnen, Martin Tegenthoff, Peter Truong, Guangbin Wang, Iain D. Wilkinson, Hans Jörg Wittsack, Hongmin Xu, Fuhua Yan, Chencheng Zhang, Vadim Zipunnikov, Helge J. Zöllner, Richard A.E. Edden

研究成果: 雜誌貢獻 › 文章 › 同行評審

90 引文斯高帕斯（Scopus）

摘要

Magnetic resonance spectroscopy (MRS) is the only biomedical imaging method that can noninvasively detect endogenous signals from the neurotransmitter γ-aminobutyric acid (GABA) in the human brain. Its increasing popularity has been aided by improvements in scanner hardware and acquisition methodology, as well as by broader access to pulse sequences that can selectively detect GABA, in particular J-difference spectral editing sequences. Nevertheless, implementations of GABA-edited MRS remain diverse across research sites, making comparisons between studies challenging. This large-scale multi-vendor, multi-site study seeks to better understand the factors that impact measurement outcomes of GABA-edited MRS. An international consortium of 24 research sites was formed. Data from 272 healthy adults were acquired on scanners from the three major MRI vendors and analyzed using the Gannet processing pipeline. MRS data were acquired in the medial parietal lobe with standard GABA+ and macromolecule- (MM-) suppressed GABA editing. The coefficient of variation across the entire cohort was 12% for GABA+ measurements and 28% for MM-suppressed GABA measurements. A multilevel analysis revealed that most of the variance (72%) in the GABA+ data was accounted for by differences between participants within-site, while site-level differences accounted for comparatively more variance (20%) than vendor-level differences (8%). For MM-suppressed GABA data, the variance was distributed equally between site- (50%) and participant-level (50%) differences. The findings show that GABA+ measurements exhibit strong agreement when implemented with a standard protocol. There is, however, increased variability for MM-suppressed GABA measurements that is attributed in part to differences in site-to-site data acquisition. This study's protocol establishes a framework for future methodological standardization of GABA-edited MRS, while the results provide valuable benchmarks for the MRS community.

原文	英語
頁（從 - 到）	32-45
頁數	14
期刊	NeuroImage
卷	159
DOIs	https://doi.org/10.1016/j.neuroimage.2017.07.021
出版狀態	已發佈 - 10月 1 2017

ASJC Scopus subject areas

神經內科
認知神經科學

UN SDG

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10.1016/j.neuroimage.2017.07.021

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Mikkelsen, M., Barker, P. B., Bhattacharyya, P. K., Brix, M. K., Buur, P. F., Cecil, K. M., Chan, K. L., Chen, D. Y. T., Craven, A. R., Cuypers, K., Dacko, M., Duncan, N. W., Dydak, U., Edmondson, D. A., Ende, G., Ersland, L., Gao, F., Greenhouse, I., Harris, A. D., ... Edden, R. A. E. (2017). Big GABA: Edited MR spectroscopy at 24 research sites. NeuroImage, 159, 32-45. https://doi.org/10.1016/j.neuroimage.2017.07.021

Mikkelsen, M, Barker, PB, Bhattacharyya, PK, Brix, MK, Buur, PF, Cecil, KM, Chan, KL, Chen, DYT, Craven, AR, Cuypers, K, Dacko, M, Duncan, NW, Dydak, U, Edmondson, DA, Ende, G, Ersland, L, Gao, F, Greenhouse, I, Harris, AD, He, N, Heba, S, Hoggard, N, Hsu, TW, Jansen, JFA, Kangarlu, A, Lange, T, Lebel, RM, Li, Y, Lin, CYE, Liou, JK, Lirng, JF, Liu, F, Ma, R, Maes, C, Moreno-Ortega, M, Murray, SO, Noah, S, Noeske, R, Noseworthy, MD, Oeltzschner, G, Prisciandaro, JJ, Puts, NAJ, Roberts, TPL, Sack, M, Sailasuta, N, Saleh, MG, Schallmo, MP, Simard, N, Swinnen, SP, Tegenthoff, M, Truong, P, Wang, G, Wilkinson, ID, Wittsack, HJ, Xu, H, Yan, F, Zhang, C, Zipunnikov, V, Zöllner, HJ & Edden, RAE 2017, 'Big GABA: Edited MR spectroscopy at 24 research sites', NeuroImage, 卷 159, 頁 32-45. https://doi.org/10.1016/j.neuroimage.2017.07.021

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title = "Big GABA: Edited MR spectroscopy at 24 research sites",

abstract = "Magnetic resonance spectroscopy (MRS) is the only biomedical imaging method that can noninvasively detect endogenous signals from the neurotransmitter γ-aminobutyric acid (GABA) in the human brain. Its increasing popularity has been aided by improvements in scanner hardware and acquisition methodology, as well as by broader access to pulse sequences that can selectively detect GABA, in particular J-difference spectral editing sequences. Nevertheless, implementations of GABA-edited MRS remain diverse across research sites, making comparisons between studies challenging. This large-scale multi-vendor, multi-site study seeks to better understand the factors that impact measurement outcomes of GABA-edited MRS. An international consortium of 24 research sites was formed. Data from 272 healthy adults were acquired on scanners from the three major MRI vendors and analyzed using the Gannet processing pipeline. MRS data were acquired in the medial parietal lobe with standard GABA+ and macromolecule- (MM-) suppressed GABA editing. The coefficient of variation across the entire cohort was 12% for GABA+ measurements and 28% for MM-suppressed GABA measurements. A multilevel analysis revealed that most of the variance (72%) in the GABA+ data was accounted for by differences between participants within-site, while site-level differences accounted for comparatively more variance (20%) than vendor-level differences (8%). For MM-suppressed GABA data, the variance was distributed equally between site- (50%) and participant-level (50%) differences. The findings show that GABA+ measurements exhibit strong agreement when implemented with a standard protocol. There is, however, increased variability for MM-suppressed GABA measurements that is attributed in part to differences in site-to-site data acquisition. This study's protocol establishes a framework for future methodological standardization of GABA-edited MRS, while the results provide valuable benchmarks for the MRS community.",

keywords = "Editing, GABA, MEGA-PRESS, MRS, Multi-site study",

author = "Mark Mikkelsen and Barker, {Peter B.} and Bhattacharyya, {Pallab K.} and Brix, {Maiken K.} and Buur, {Pieter F.} and Cecil, {Kim M.} and Chan, {Kimberly L.} and Chen, {David Y.T.} and Craven, {Alexander R.} and Koen Cuypers and Michael Dacko and Duncan, {Niall W.} and Ulrike Dydak and Edmondson, {David A.} and Gabriele Ende and Lars Ersland and Fei Gao and Ian Greenhouse and Harris, {Ashley D.} and Naying He and Stefanie Heba and Nigel Hoggard and Hsu, {Tun Wei} and Jansen, {Jacobus F.A.} and Alayar Kangarlu and Thomas Lange and Lebel, {R. Marc} and Yan Li and Lin, {Chien Yuan E.} and Liou, {Jy Kang} and Lirng, {Jiing Feng} and Feng Liu and Ruoyun Ma and Celine Maes and Marta Moreno-Ortega and Murray, {Scott O.} and Sean Noah and Ralph Noeske and Noseworthy, {Michael D.} and Georg Oeltzschner and Prisciandaro, {James J.} and Puts, {Nicolaas A.J.} and Roberts, {Timothy P.L.} and Markus Sack and Napapon Sailasuta and Saleh, {Muhammad G.} and Schallmo, {Michael Paul} and Nicholas Simard and Swinnen, {Stephan P.} and Martin Tegenthoff and Peter Truong and Guangbin Wang and Wilkinson, {Iain D.} and Wittsack, {Hans J{\"o}rg} and Hongmin Xu and Fuhua Yan and Chencheng Zhang and Vadim Zipunnikov and Z{\"o}llner, {Helge J.} and Edden, {Richard A.E.}",

note = "Funding Information: This work was supported by NIH grants R01 EB016089, R01 EB023963 and P41 EB015909. Data collection was supported by the Shandong Provincial Key Research and Development Plan of China (2016ZDJS07A16) and the National Natural Science Foundation of China for Young Scholars (no. 81601479). IDW thanks Mrs. J. Bigley of the University of Sheffield MRI Unit for her assistance with data acquisition. JJP was supported by NIAAA grant K23 AA020842. MPS was supported by NIH grant F32 EY025121. NAJP receives salary support from NIH grant K99 MH107719. The authors acknowledge implementation contributions from a number of employees of Siemens Medical Solutions, including Dr. Keith Heberlein and Dr. Sinyeob Ahn, to the Siemens WIP sequences, which are shared with several research sites under sequence-specific agreements. Publisher Copyright: {\textcopyright} 2017 Elsevier Inc.",

year = "2017",

month = oct,

day = "1",

doi = "10.1016/j.neuroimage.2017.07.021",

language = "English",

volume = "159",

pages = "32--45",

journal = "NeuroImage",

issn = "1053-8119",

publisher = "Academic Press Inc.",

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TY - JOUR

T1 - Big GABA

T2 - Edited MR spectroscopy at 24 research sites

AU - Mikkelsen, Mark

AU - Barker, Peter B.

AU - Bhattacharyya, Pallab K.

AU - Brix, Maiken K.

AU - Buur, Pieter F.

AU - Cecil, Kim M.

AU - Chan, Kimberly L.

AU - Chen, David Y.T.

AU - Craven, Alexander R.

AU - Cuypers, Koen

AU - Dacko, Michael

AU - Duncan, Niall W.

AU - Dydak, Ulrike

AU - Edmondson, David A.

AU - Ende, Gabriele

AU - Ersland, Lars

AU - Gao, Fei

AU - Greenhouse, Ian

AU - Harris, Ashley D.

AU - He, Naying

AU - Heba, Stefanie

AU - Hoggard, Nigel

AU - Hsu, Tun Wei

AU - Jansen, Jacobus F.A.

AU - Kangarlu, Alayar

AU - Lange, Thomas

AU - Lebel, R. Marc

AU - Li, Yan

AU - Lin, Chien Yuan E.

AU - Liou, Jy Kang

AU - Lirng, Jiing Feng

AU - Liu, Feng

AU - Ma, Ruoyun

AU - Maes, Celine

AU - Moreno-Ortega, Marta

AU - Murray, Scott O.

AU - Noah, Sean

AU - Noeske, Ralph

AU - Noseworthy, Michael D.

AU - Oeltzschner, Georg

AU - Prisciandaro, James J.

AU - Puts, Nicolaas A.J.

AU - Roberts, Timothy P.L.

AU - Sack, Markus

AU - Sailasuta, Napapon

AU - Saleh, Muhammad G.

AU - Schallmo, Michael Paul

AU - Simard, Nicholas

AU - Swinnen, Stephan P.

AU - Tegenthoff, Martin

AU - Truong, Peter

AU - Wang, Guangbin

AU - Wilkinson, Iain D.

AU - Wittsack, Hans Jörg

AU - Xu, Hongmin

AU - Yan, Fuhua

AU - Zhang, Chencheng

AU - Zipunnikov, Vadim

AU - Zöllner, Helge J.

AU - Edden, Richard A.E.

N1 - Funding Information: This work was supported by NIH grants R01 EB016089, R01 EB023963 and P41 EB015909. Data collection was supported by the Shandong Provincial Key Research and Development Plan of China (2016ZDJS07A16) and the National Natural Science Foundation of China for Young Scholars (no. 81601479). IDW thanks Mrs. J. Bigley of the University of Sheffield MRI Unit for her assistance with data acquisition. JJP was supported by NIAAA grant K23 AA020842. MPS was supported by NIH grant F32 EY025121. NAJP receives salary support from NIH grant K99 MH107719. The authors acknowledge implementation contributions from a number of employees of Siemens Medical Solutions, including Dr. Keith Heberlein and Dr. Sinyeob Ahn, to the Siemens WIP sequences, which are shared with several research sites under sequence-specific agreements. Publisher Copyright: © 2017 Elsevier Inc.

PY - 2017/10/1

Y1 - 2017/10/1

N2 - Magnetic resonance spectroscopy (MRS) is the only biomedical imaging method that can noninvasively detect endogenous signals from the neurotransmitter γ-aminobutyric acid (GABA) in the human brain. Its increasing popularity has been aided by improvements in scanner hardware and acquisition methodology, as well as by broader access to pulse sequences that can selectively detect GABA, in particular J-difference spectral editing sequences. Nevertheless, implementations of GABA-edited MRS remain diverse across research sites, making comparisons between studies challenging. This large-scale multi-vendor, multi-site study seeks to better understand the factors that impact measurement outcomes of GABA-edited MRS. An international consortium of 24 research sites was formed. Data from 272 healthy adults were acquired on scanners from the three major MRI vendors and analyzed using the Gannet processing pipeline. MRS data were acquired in the medial parietal lobe with standard GABA+ and macromolecule- (MM-) suppressed GABA editing. The coefficient of variation across the entire cohort was 12% for GABA+ measurements and 28% for MM-suppressed GABA measurements. A multilevel analysis revealed that most of the variance (72%) in the GABA+ data was accounted for by differences between participants within-site, while site-level differences accounted for comparatively more variance (20%) than vendor-level differences (8%). For MM-suppressed GABA data, the variance was distributed equally between site- (50%) and participant-level (50%) differences. The findings show that GABA+ measurements exhibit strong agreement when implemented with a standard protocol. There is, however, increased variability for MM-suppressed GABA measurements that is attributed in part to differences in site-to-site data acquisition. This study's protocol establishes a framework for future methodological standardization of GABA-edited MRS, while the results provide valuable benchmarks for the MRS community.

AB - Magnetic resonance spectroscopy (MRS) is the only biomedical imaging method that can noninvasively detect endogenous signals from the neurotransmitter γ-aminobutyric acid (GABA) in the human brain. Its increasing popularity has been aided by improvements in scanner hardware and acquisition methodology, as well as by broader access to pulse sequences that can selectively detect GABA, in particular J-difference spectral editing sequences. Nevertheless, implementations of GABA-edited MRS remain diverse across research sites, making comparisons between studies challenging. This large-scale multi-vendor, multi-site study seeks to better understand the factors that impact measurement outcomes of GABA-edited MRS. An international consortium of 24 research sites was formed. Data from 272 healthy adults were acquired on scanners from the three major MRI vendors and analyzed using the Gannet processing pipeline. MRS data were acquired in the medial parietal lobe with standard GABA+ and macromolecule- (MM-) suppressed GABA editing. The coefficient of variation across the entire cohort was 12% for GABA+ measurements and 28% for MM-suppressed GABA measurements. A multilevel analysis revealed that most of the variance (72%) in the GABA+ data was accounted for by differences between participants within-site, while site-level differences accounted for comparatively more variance (20%) than vendor-level differences (8%). For MM-suppressed GABA data, the variance was distributed equally between site- (50%) and participant-level (50%) differences. The findings show that GABA+ measurements exhibit strong agreement when implemented with a standard protocol. There is, however, increased variability for MM-suppressed GABA measurements that is attributed in part to differences in site-to-site data acquisition. This study's protocol establishes a framework for future methodological standardization of GABA-edited MRS, while the results provide valuable benchmarks for the MRS community.

KW - Editing

KW - GABA

KW - MEGA-PRESS

KW - MRS

KW - Multi-site study

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DO - 10.1016/j.neuroimage.2017.07.021

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VL - 159

SP - 32

EP - 45

JO - NeuroImage

JF - NeuroImage

SN - 1053-8119

ER -

Big GABA: Edited MR spectroscopy at 24 research sites

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UN SDG

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