Normative modelling of brain morphometry across the lifespan with CentileBrain: algorithm benchmarking and model optimisation

ENIGMA Lifespan Working Group

doi:10.1016/S2589-7500(23)00250-9

Normative modelling of brain morphometry across the lifespan with CentileBrain: algorithm benchmarking and model optimisation

ENIGMA Lifespan Working Group

University of British Columbia
Icahn School of Medicine at Mount Sinai
Vrije Universiteit Amsterdam
University of New South Wales
Harvard University
MRC Centre for Neuropsychiatric Genetics and Genomics
Groupe d'Imagerie Neurofonctionnelle
Erasmus School of Social and Behavioural Sciences
Charité – Universitätsmedizin Berlin
Max Planck Institute for Psycholinguistics
Donders Institute for Brain, Cognition and Behaviour
Boston Children's Hospital
University of Münster
Heidelberg University
Utrecht University
Fudan University
University of Oslo
Leiden University
Keck School of Medicine of USC

Research output: Contribution to a Journal (Peer & Non Peer) › Review article › peer-review

60 Citations (Scopus)

Abstract

The value of normative models in research and clinical practice relies on their robustness and a systematic comparison of different modelling algorithms and parameters; however, this has not been done to date. We aimed to identify the optimal approach for normative modelling of brain morphometric data through systematic empirical benchmarking, by quantifying the accuracy of different algorithms and identifying parameters that optimised model performance. We developed this framework with regional morphometric data from 37 407 healthy individuals (53% female and 47% male; aged 3–90 years) from 87 datasets from Europe, Australia, the USA, South Africa, and east Asia following a comparative evaluation of eight algorithms and multiple covariate combinations pertaining to image acquisition and quality, parcellation software versions, global neuroimaging measures, and longitudinal stability. The multivariate fractional polynomial regression (MFPR) emerged as the preferred algorithm, optimised with non-linear polynomials for age and linear effects of global measures as covariates. The MFPR models showed excellent accuracy across the lifespan and within distinct age-bins and longitudinal stability over a 2-year period. The performance of all MFPR models plateaued at sample sizes exceeding 3000 study participants. This model can inform about the biological and behavioural implications of deviations from typical age-related neuroanatomical changes and support future study designs. The model and scripts described here are freely available through CentileBrain.

Original language	English
Pages (from-to)	e211-e221
Journal	The Lancet Digital Health
Volume	6
Issue number	3
DOIs	https://doi.org/10.1016/S2589-7500(23)00250-9
Publication status	Published - Mar 2024

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10.1016/S2589-7500(23)00250-9

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@article{a5a498228263425a88762634242bc6bd,

title = "Normative modelling of brain morphometry across the lifespan with CentileBrain: algorithm benchmarking and model optimisation",

abstract = "The value of normative models in research and clinical practice relies on their robustness and a systematic comparison of different modelling algorithms and parameters; however, this has not been done to date. We aimed to identify the optimal approach for normative modelling of brain morphometric data through systematic empirical benchmarking, by quantifying the accuracy of different algorithms and identifying parameters that optimised model performance. We developed this framework with regional morphometric data from 37 407 healthy individuals (53\% female and 47\% male; aged 3–90 years) from 87 datasets from Europe, Australia, the USA, South Africa, and east Asia following a comparative evaluation of eight algorithms and multiple covariate combinations pertaining to image acquisition and quality, parcellation software versions, global neuroimaging measures, and longitudinal stability. The multivariate fractional polynomial regression (MFPR) emerged as the preferred algorithm, optimised with non-linear polynomials for age and linear effects of global measures as covariates. The MFPR models showed excellent accuracy across the lifespan and within distinct age-bins and longitudinal stability over a 2-year period. The performance of all MFPR models plateaued at sample sizes exceeding 3000 study participants. This model can inform about the biological and behavioural implications of deviations from typical age-related neuroanatomical changes and support future study designs. The model and scripts described here are freely available through CentileBrain.",

author = "\{ENIGMA Lifespan Working Group\} and Ruiyang Ge and Yuetong Yu and Qi, \{Yi Xuan\} and Fan, \{Yu nan\} and Shiyu Chen and Chuntong Gao and Haas, \{Shalaila S.\} and Faye New and Boomsma, \{Dorret I.\} and Henry Brodaty and Brouwer, \{Rachel M.\} and Randy Buckner and Xavier Caseras and Fabrice Crivello and Crone, \{Eveline A.\} and Susanne Erk and Fisher, \{Simon E.\} and Barbara Franke and Glahn, \{David C.\} and Udo Dannlowski and Dominik Grotegerd and Oliver Gruber and \{Hulshoff Pol\}, \{Hilleke E.\} and Gunter Schumann and Tamnes, \{Christian K.\} and Henrik Walter and Wierenga, \{Lara M.\} and Neda Jahanshad and Thompson, \{Paul M.\} and Sophia Frangou and Ingrid Agartz and Philip Asherson and Rosa Ayesa-Arriola and Nerisa Banaj and Tobias Banaschewski and Sarah Baumeister and Alessandro Bertolino and Stefan Borgwardt and Josiane Bourque and Daniel Brandeis and Alan Breier and Buitelaar, \{Jan K.\} and Cannon, \{Dara M.\} and Simon Cervenka and Conrod, \{Patricia J.\} and Benedicto Crespo-Facorro and Davey, \{Christopher G.\} and \{de Haan\}, Lieuwe and \{de Zubicaray\}, \{Greig I.\} and \{Di Giorgio\}, Annabella and Thomas Frodl and Patricia Gruner and Gur, \{Raquel E.\} and Gur, \{Ruben C.\} and Harrison, \{Ben J.\} and Hatton, \{Sean N.\} and Ian Hickie and Howells, \{Fleur M.\} and Chaim Huyser and Jernigan, \{Terry L.\} and Jiyang Jiang and Joska, \{John A.\} and Kahn, \{Ren{\'e} S.\} and Kalnin, \{Andrew J.\} and Kochan, \{Nicole A.\} and Sanne Koops and Jonna Kuntsi and Jim Lagopoulos and Luisa Lazaro and Lebedeva, \{Irina S.\} and Christine Lochner and Martin, \{Nicholas G.\} and Bernard Mazoyer and McDonald, \{Brenna C.\} and Colm McDonald and McMahon, \{Katie L.\} and Sarah Medland and Amirhossein Modabbernia and Benson Mwangi and Tomohiro Nakao and Lars Nyberg and Fabrizio Piras and Portella, \{Maria J.\} and Jiang Qiu and Roffman, \{Joshua L.\} and Sachdev, \{Perminder S.\} and Nicole Sanford and Satterthwaite, \{Theodore D.\} and Saykin, \{Andrew J.\} and Sellgren, \{Carl M.\} and Kang Sim and Smoller, \{Jordan W.\} and Soares, \{Jair C.\} and Sommer, \{Iris E.\} and Gianfranco Spalletta and Stein, \{Dan J.\} and Thomopoulos, \{Sophia I.\} and Tomyshev, \{Alexander S.\} and Diana Tordesillas-Guti{\'e}rrez and Trollor, \{Julian N.\}",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY 4.0 license",

year = "2024",

month = mar,

doi = "10.1016/S2589-7500(23)00250-9",

language = "English",

volume = "6",

pages = "e211--e221",

journal = "The Lancet Digital Health",

issn = "2589-7500",

publisher = "Elsevier Ltd",

number = "3",

}

TY - JOUR

T1 - Normative modelling of brain morphometry across the lifespan with CentileBrain

T2 - algorithm benchmarking and model optimisation

AU - ENIGMA Lifespan Working Group

AU - Ge, Ruiyang

AU - Yu, Yuetong

AU - Qi, Yi Xuan

AU - Fan, Yu nan

AU - Chen, Shiyu

AU - Gao, Chuntong

AU - Haas, Shalaila S.

AU - New, Faye

AU - Boomsma, Dorret I.

AU - Brodaty, Henry

AU - Brouwer, Rachel M.

AU - Buckner, Randy

AU - Caseras, Xavier

AU - Crivello, Fabrice

AU - Crone, Eveline A.

AU - Erk, Susanne

AU - Fisher, Simon E.

AU - Franke, Barbara

AU - Glahn, David C.

AU - Dannlowski, Udo

AU - Grotegerd, Dominik

AU - Gruber, Oliver

AU - Hulshoff Pol, Hilleke E.

AU - Schumann, Gunter

AU - Tamnes, Christian K.

AU - Walter, Henrik

AU - Wierenga, Lara M.

AU - Jahanshad, Neda

AU - Thompson, Paul M.

AU - Frangou, Sophia

AU - Agartz, Ingrid

AU - Asherson, Philip

AU - Ayesa-Arriola, Rosa

AU - Banaj, Nerisa

AU - Banaschewski, Tobias

AU - Baumeister, Sarah

AU - Bertolino, Alessandro

AU - Borgwardt, Stefan

AU - Bourque, Josiane

AU - Brandeis, Daniel

AU - Breier, Alan

AU - Buitelaar, Jan K.

AU - Cannon, Dara M.

AU - Cervenka, Simon

AU - Conrod, Patricia J.

AU - Crespo-Facorro, Benedicto

AU - Davey, Christopher G.

AU - de Haan, Lieuwe

AU - de Zubicaray, Greig I.

AU - Di Giorgio, Annabella

AU - Frodl, Thomas

AU - Gruner, Patricia

AU - Gur, Raquel E.

AU - Gur, Ruben C.

AU - Harrison, Ben J.

AU - Hatton, Sean N.

AU - Hickie, Ian

AU - Howells, Fleur M.

AU - Huyser, Chaim

AU - Jernigan, Terry L.

AU - Jiang, Jiyang

AU - Joska, John A.

AU - Kahn, René S.

AU - Kalnin, Andrew J.

AU - Kochan, Nicole A.

AU - Koops, Sanne

AU - Kuntsi, Jonna

AU - Lagopoulos, Jim

AU - Lazaro, Luisa

AU - Lebedeva, Irina S.

AU - Lochner, Christine

AU - Martin, Nicholas G.

AU - Mazoyer, Bernard

AU - McDonald, Brenna C.

AU - McDonald, Colm

AU - McMahon, Katie L.

AU - Medland, Sarah

AU - Modabbernia, Amirhossein

AU - Mwangi, Benson

AU - Nakao, Tomohiro

AU - Nyberg, Lars

AU - Piras, Fabrizio

AU - Portella, Maria J.

AU - Qiu, Jiang

AU - Roffman, Joshua L.

AU - Sachdev, Perminder S.

AU - Sanford, Nicole

AU - Satterthwaite, Theodore D.

AU - Saykin, Andrew J.

AU - Sellgren, Carl M.

AU - Sim, Kang

AU - Smoller, Jordan W.

AU - Soares, Jair C.

AU - Sommer, Iris E.

AU - Spalletta, Gianfranco

AU - Stein, Dan J.

AU - Thomopoulos, Sophia I.

AU - Tomyshev, Alexander S.

AU - Tordesillas-Gutiérrez, Diana

AU - Trollor, Julian N.

PY - 2024/3

Y1 - 2024/3

N2 - The value of normative models in research and clinical practice relies on their robustness and a systematic comparison of different modelling algorithms and parameters; however, this has not been done to date. We aimed to identify the optimal approach for normative modelling of brain morphometric data through systematic empirical benchmarking, by quantifying the accuracy of different algorithms and identifying parameters that optimised model performance. We developed this framework with regional morphometric data from 37 407 healthy individuals (53% female and 47% male; aged 3–90 years) from 87 datasets from Europe, Australia, the USA, South Africa, and east Asia following a comparative evaluation of eight algorithms and multiple covariate combinations pertaining to image acquisition and quality, parcellation software versions, global neuroimaging measures, and longitudinal stability. The multivariate fractional polynomial regression (MFPR) emerged as the preferred algorithm, optimised with non-linear polynomials for age and linear effects of global measures as covariates. The MFPR models showed excellent accuracy across the lifespan and within distinct age-bins and longitudinal stability over a 2-year period. The performance of all MFPR models plateaued at sample sizes exceeding 3000 study participants. This model can inform about the biological and behavioural implications of deviations from typical age-related neuroanatomical changes and support future study designs. The model and scripts described here are freely available through CentileBrain.

AB - The value of normative models in research and clinical practice relies on their robustness and a systematic comparison of different modelling algorithms and parameters; however, this has not been done to date. We aimed to identify the optimal approach for normative modelling of brain morphometric data through systematic empirical benchmarking, by quantifying the accuracy of different algorithms and identifying parameters that optimised model performance. We developed this framework with regional morphometric data from 37 407 healthy individuals (53% female and 47% male; aged 3–90 years) from 87 datasets from Europe, Australia, the USA, South Africa, and east Asia following a comparative evaluation of eight algorithms and multiple covariate combinations pertaining to image acquisition and quality, parcellation software versions, global neuroimaging measures, and longitudinal stability. The multivariate fractional polynomial regression (MFPR) emerged as the preferred algorithm, optimised with non-linear polynomials for age and linear effects of global measures as covariates. The MFPR models showed excellent accuracy across the lifespan and within distinct age-bins and longitudinal stability over a 2-year period. The performance of all MFPR models plateaued at sample sizes exceeding 3000 study participants. This model can inform about the biological and behavioural implications of deviations from typical age-related neuroanatomical changes and support future study designs. The model and scripts described here are freely available through CentileBrain.

UR - https://www.scopus.com/pages/publications/85185553011

U2 - 10.1016/S2589-7500(23)00250-9

DO - 10.1016/S2589-7500(23)00250-9

M3 - Review article

C2 - 38395541

AN - SCOPUS:85185553011

SN - 2589-7500

VL - 6

SP - e211-e221

JO - The Lancet Digital Health

JF - The Lancet Digital Health

IS - 3

ER -

Normative modelling of brain morphometry across the lifespan with CentileBrain: algorithm benchmarking and model optimisation

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