TY - JOUR
T1 - An Empirical Comparison of Meta- and Mega-Analysis With Data From the ENIGMA Obsessive-Compulsive Disorder Working Group
AU - ENIGMA-OCD Working-Group
AU - Boedhoe, Premika S.W.
AU - Heymans, Martijn W.
AU - Schmaal, Lianne
AU - Abe, Yoshinari
AU - Alonso, Pino
AU - Ameis, Stephanie H.
AU - Anticevic, Alan
AU - Arnold, Paul D.
AU - Batistuzzo, Marcelo C.
AU - Benedetti, Francesco
AU - Beucke, Jan C.
AU - Bollettini, Irene
AU - Bose, Anushree
AU - Brem, Silvia
AU - Calvo, Anna
AU - Calvo, Rosa
AU - Cheng, Yuqi
AU - Cho, Kang Ik K.
AU - Ciullo, Valentina
AU - Dallaspezia, Sara
AU - Denys, Damiaan
AU - Feusner, Jamie D.
AU - Fitzgerald, Kate D.
AU - Fouche, Jean Paul
AU - Fridgeirsson, Egill A.
AU - Gruner, Patricia
AU - Hanna, Gregory L.
AU - Hibar, Derrek P.
AU - Hoexter, Marcelo Q.
AU - Hu, Hao
AU - Huyser, Chaim
AU - Jahanshad, Neda
AU - James, Anthony
AU - Kathmann, Norbert
AU - Kaufmann, Christian
AU - Koch, Kathrin
AU - Kwon, Jun Soo
AU - Lazaro, Luisa
AU - Lochner, Christine
AU - Marsh, Rachel
AU - Martínez-Zalacaín, Ignacio
AU - Mataix-Cols, David
AU - Menchón, José M.
AU - Minuzzi, Luciano
AU - Morer, Astrid
AU - Nakamae, Takashi
AU - Nakao, Tomohiro
AU - Narayanaswamy, Janardhanan C.
AU - Szeszko, Philip R.
AU - Stein, Dan J.
N1 - Publisher Copyright:
© Copyright © 2019 Boedhoe, Heymans, Schmaal, Abe, Alonso, Ameis, Anticevic, Arnold, Batistuzzo, Benedetti, Beucke, Bollettini, Bose, Brem, Calvo, Calvo, Cheng, Cho, Ciullo, Dallaspezia, Denys, Feusner, Fitzgerald, Fouche, Fridgeirsson, Gruner, Hanna, Hibar, Hoexter, Hu, Huyser, Jahanshad, James, Kathmann, Kaufmann, Koch, Kwon, Lazaro, Lochner, Marsh, Martínez-Zalacaín, Mataix-Cols, Menchón, Minuzzi, Morer, Nakamae, Nakao, Narayanaswamy, Nishida, Nurmi, O'Neill, Piacentini, Piras, Piras, Reddy, Reess, Sakai, Sato, Simpson, Soreni, Soriano-Mas, Spalletta, Stevens, Szeszko, Tolin, van Wingen, Venkatasubramanian, Walitza, Wang, Yun, ENIGMA-OCD Working-Group, Thompson, Stein, van den Heuvel and Twisk.
PY - 2019/1/8
Y1 - 2019/1/8
N2 - Objective: Brain imaging communities focusing on different diseases have increasingly started to collaborate and to pool data to perform well-powered meta- and mega-analyses. Some methodologists claim that a one-stage individual-participant data (IPD) mega-analysis can be superior to a two-stage aggregated data meta-analysis, since more detailed computations can be performed in a mega-analysis. Before definitive conclusions regarding the performance of either method can be drawn, it is necessary to critically evaluate the methodology of, and results obtained by, meta- and mega-analyses. Methods: Here, we compare the inverse variance weighted random-effect meta-analysis model with a multiple linear regression mega-analysis model, as well as with a linear mixed-effects random-intercept mega-analysis model, using data from 38 cohorts including 3,665 participants of the ENIGMA-OCD consortium. We assessed the effect sizes and standard errors, and the fit of the models, to evaluate the performance of the different methods. Results: The mega-analytical models showed lower standard errors and narrower confidence intervals than the meta-analysis. Similar standard errors and confidence intervals were found for the linear regression and linear mixed-effects random-intercept models. Moreover, the linear mixed-effects random-intercept models showed better fit indices compared to linear regression mega-analytical models. Conclusions: Our findings indicate that results obtained by meta- and mega-analysis differ, in favor of the latter. In multi-center studies with a moderate amount of variation between cohorts, a linear mixed-effects random-intercept mega-analytical framework appears to be the better approach to investigate structural neuroimaging data.
AB - Objective: Brain imaging communities focusing on different diseases have increasingly started to collaborate and to pool data to perform well-powered meta- and mega-analyses. Some methodologists claim that a one-stage individual-participant data (IPD) mega-analysis can be superior to a two-stage aggregated data meta-analysis, since more detailed computations can be performed in a mega-analysis. Before definitive conclusions regarding the performance of either method can be drawn, it is necessary to critically evaluate the methodology of, and results obtained by, meta- and mega-analyses. Methods: Here, we compare the inverse variance weighted random-effect meta-analysis model with a multiple linear regression mega-analysis model, as well as with a linear mixed-effects random-intercept mega-analysis model, using data from 38 cohorts including 3,665 participants of the ENIGMA-OCD consortium. We assessed the effect sizes and standard errors, and the fit of the models, to evaluate the performance of the different methods. Results: The mega-analytical models showed lower standard errors and narrower confidence intervals than the meta-analysis. Similar standard errors and confidence intervals were found for the linear regression and linear mixed-effects random-intercept models. Moreover, the linear mixed-effects random-intercept models showed better fit indices compared to linear regression mega-analytical models. Conclusions: Our findings indicate that results obtained by meta- and mega-analysis differ, in favor of the latter. In multi-center studies with a moderate amount of variation between cohorts, a linear mixed-effects random-intercept mega-analytical framework appears to be the better approach to investigate structural neuroimaging data.
KW - IPD meta-analysis
KW - MRI
KW - linear mixed-effect models
KW - mega-analysis
KW - neuroimaging
UR - http://www.scopus.com/inward/record.url?scp=85068366646&partnerID=8YFLogxK
U2 - 10.3389/fninf.2018.00102
DO - 10.3389/fninf.2018.00102
M3 - Article
AN - SCOPUS:85068366646
SN - 1662-5196
VL - 12
JO - Frontiers in Neuroinformatics
JF - Frontiers in Neuroinformatics
M1 - 102
ER -