Mind the gap: Performance metric evaluation in brain-age prediction

Ann Marie G. de Lange; Melis Anatürk; Jaroslav Rokicki; Laura K.M. Han; Katja Franke; Dag Alnæs; Klaus P. Ebmeier; Bogdan Draganski; Tobias Kaufmann; Lars T. Westlye; Tim Hahn; James H. Cole

doi:10.1002/hbm.25837

Mind the gap: Performance metric evaluation in brain-age prediction

Ann Marie G. de Lange, Melis Anatürk, Jaroslav Rokicki, Laura K.M. Han, Katja Franke, Dag Alnæs, Klaus P. Ebmeier, Bogdan Draganski, Tobias Kaufmann, Lars T. Westlye, Tim Hahn, James H. Cole

Research output: Contribution to journal › Article › peer-review

72 Citations (Scopus)

Abstract

Estimating age based on neuroimaging-derived data has become a popular approach to developing markers for brain integrity and health. While a variety of machine-learning algorithms can provide accurate predictions of age based on brain characteristics, there is significant variation in model accuracy reported across studies. We predicted age in two population-based datasets, and assessed the effects of age range, sample size and age-bias correction on the model performance metrics Pearson's correlation coefficient (r), the coefficient of determination (R²), Root Mean Squared Error (RMSE) and Mean Absolute Error (MAE). The results showed that these metrics vary considerably depending on cohort age range; r and R² values are lower when measured in samples with a narrower age range. RMSE and MAE are also lower in samples with a narrower age range due to smaller errors/brain age delta values when predictions are closer to the mean age of the group. Across subsets with different age ranges, performance metrics improve with increasing sample size. Performance metrics further vary depending on prediction variance as well as mean age difference between training and test sets, and age-bias corrected metrics indicate high accuracy—also for models showing poor initial performance. In conclusion, performance metrics used for evaluating age prediction models depend on cohort and study-specific data characteristics, and cannot be directly compared across different studies. Since age-bias corrected metrics generally indicate high accuracy, even for poorly performing models, inspection of uncorrected model results provides important information about underlying model attributes such as prediction variance.

Original language	English
Journal	Human Brain Mapping
DOIs	https://doi.org/10.1002/hbm.25837
Publication status	Accepted/In press - 2022
Externally published	Yes

Bibliographical note

Funding Information:
This research was conducted using the UK Biobank under Application 27412. While working on this study, the authors received funding from the Swiss National Science Foundation (Ann‐Marie G. de Lange; PZ00P3_193658; Bogdan Draganski; NCCR Synapsy, project grants Number 32003B_135679, 32003B_159780, 324730_192755 and CRSK‐3_190185), the Leenaards Foundation (Bogdan Draganski), the Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Ageing and Dementia (Melis Anatürk; 5R24AG061421‐03), the UK Medical Research Council (James H. Cole and Melis Anatürk; MR/R024790/2, Klaus P. Ebmeier; G1001354), the HDH Wills 1965 Charitable Trust (Klaus P. Ebmeier; 1117747), the research Council of Norway (Lars T. Westlye; 273345, 249795, 223273; Tobias Kaufmann; 276082), the European Research Council under the European Union's Horizon 2020 research and innovation programme (Lars T. Westlye; 802998), the South‐East Norway Regional Health Authority (Lars T. Westlye; 2015073, 2019107), the German Research Foundation (Katja Franke; FR 3709/1‐2; Tim Hahn; HA7070/2‐2, HA7070/3, HA7070/4), the Interdisciplinary Center for Clinical Research (IZKF) of the medical faculty of Münster (Tim Hahn; MzH 3/020/20), the Interdisciplinary Center for Clinical Research (IZKF) of the Jena University hospital (Katja Franke; AMSP 07) and the ERA‐Net Cofund through the ERA PerMed project “IMPLEMENT” (Jaroslav Rokicki). We thank Dr Dónal Hill, Institute of Physics, École polytechnique fédérale de Lausanne (EPFL), for valuable statistical input. Open access funding enabled and organized by Projekt DEAL.

Funding Information:
Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Aging and Dementia, Grant/Award Number: 5R24AG061421‐03; Deutsche Forschungsgemeinschaft, Grant/Award Numbers: FR 3709/1‐2, HA7070/2‐2, HA7070/3, HA7070/4; ERA‐net Cofound, Grant/Award Number: ERA PerMed project ”IMPLEMENT”; Fondation Leenaards; H2020 European Research Council, Grant/Award Number: 802998; HDH Wills 1965 Charitable Trust, Grant/Award Number: 1117747; Helse Sør‐Øst RHF, Grant/Award Numbers: 2015073, 2019107; Interdisciplinary Center for Clinical Research of the Jena University hospital, Grant/Award Number: AMSP 07; Interdisciplinary Center for Clinical Research of the Medical Faculty of Münster, Grant/Award Number: MzH 3/020/20; Medical Research Council, Grant/Award Numbers: G1001354, MR/R024790/2; Norges Forskningsråd, Grant/Award Numbers: 223273, 249795, 273345, 276082; Swiss National Science Foundation, Grant/Award Numbers: 32003B_135679, 32003B_159780, 324730_192755, CRSK‐3_190185, PZ00P3_193658 Funding information

Publisher Copyright:
© 2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.

ASJC Scopus Subject Areas

Anatomy
Radiological and Ultrasound Technology
Radiology Nuclear Medicine and imaging
Neurology
Clinical Neurology

PubMed: MeSH publication types

Journal Article
Research Support, Non-U.S. Gov't

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10.1002/hbm.25837

Cite this

@article{43f7852fc8c644eda257018980f79f6f,

title = "Mind the gap: Performance metric evaluation in brain-age prediction",

abstract = "Estimating age based on neuroimaging-derived data has become a popular approach to developing markers for brain integrity and health. While a variety of machine-learning algorithms can provide accurate predictions of age based on brain characteristics, there is significant variation in model accuracy reported across studies. We predicted age in two population-based datasets, and assessed the effects of age range, sample size and age-bias correction on the model performance metrics Pearson's correlation coefficient (r), the coefficient of determination (R2), Root Mean Squared Error (RMSE) and Mean Absolute Error (MAE). The results showed that these metrics vary considerably depending on cohort age range; r and R2 values are lower when measured in samples with a narrower age range. RMSE and MAE are also lower in samples with a narrower age range due to smaller errors/brain age delta values when predictions are closer to the mean age of the group. Across subsets with different age ranges, performance metrics improve with increasing sample size. Performance metrics further vary depending on prediction variance as well as mean age difference between training and test sets, and age-bias corrected metrics indicate high accuracy—also for models showing poor initial performance. In conclusion, performance metrics used for evaluating age prediction models depend on cohort and study-specific data characteristics, and cannot be directly compared across different studies. Since age-bias corrected metrics generally indicate high accuracy, even for poorly performing models, inspection of uncorrected model results provides important information about underlying model attributes such as prediction variance.",

author = "{de Lange}, {Ann Marie G.} and Melis Anat{\"u}rk and Jaroslav Rokicki and Han, {Laura K.M.} and Katja Franke and Dag Aln{\ae}s and Ebmeier, {Klaus P.} and Bogdan Draganski and Tobias Kaufmann and Westlye, {Lars T.} and Tim Hahn and Cole, {James H.}",

note = "Funding Information: This research was conducted using the UK Biobank under Application 27412. While working on this study, the authors received funding from the Swiss National Science Foundation (Ann‐Marie G. de Lange; PZ00P3_193658; Bogdan Draganski; NCCR Synapsy, project grants Number 32003B_135679, 32003B_159780, 324730_192755 and CRSK‐3_190185), the Leenaards Foundation (Bogdan Draganski), the Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Ageing and Dementia (Melis Anat{\"u}rk; 5R24AG061421‐03), the UK Medical Research Council (James H. Cole and Melis Anat{\"u}rk; MR/R024790/2, Klaus P. Ebmeier; G1001354), the HDH Wills 1965 Charitable Trust (Klaus P. Ebmeier; 1117747), the research Council of Norway (Lars T. Westlye; 273345, 249795, 223273; Tobias Kaufmann; 276082), the European Research Council under the European Union's Horizon 2020 research and innovation programme (Lars T. Westlye; 802998), the South‐East Norway Regional Health Authority (Lars T. Westlye; 2015073, 2019107), the German Research Foundation (Katja Franke; FR 3709/1‐2; Tim Hahn; HA7070/2‐2, HA7070/3, HA7070/4), the Interdisciplinary Center for Clinical Research (IZKF) of the medical faculty of M{\"u}nster (Tim Hahn; MzH 3/020/20), the Interdisciplinary Center for Clinical Research (IZKF) of the Jena University hospital (Katja Franke; AMSP 07) and the ERA‐Net Cofund through the ERA PerMed project “IMPLEMENT” (Jaroslav Rokicki). We thank Dr D{\'o}nal Hill, Institute of Physics, {\'E}cole polytechnique f{\'e}d{\'e}rale de Lausanne (EPFL), for valuable statistical input. Open access funding enabled and organized by Projekt DEAL. Funding Information: Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Aging and Dementia, Grant/Award Number: 5R24AG061421‐03; Deutsche Forschungsgemeinschaft, Grant/Award Numbers: FR 3709/1‐2, HA7070/2‐2, HA7070/3, HA7070/4; ERA‐net Cofound, Grant/Award Number: ERA PerMed project ”IMPLEMENT”; Fondation Leenaards; H2020 European Research Council, Grant/Award Number: 802998; HDH Wills 1965 Charitable Trust, Grant/Award Number: 1117747; Helse S{\o}r‐{\O}st RHF, Grant/Award Numbers: 2015073, 2019107; Interdisciplinary Center for Clinical Research of the Jena University hospital, Grant/Award Number: AMSP 07; Interdisciplinary Center for Clinical Research of the Medical Faculty of M{\"u}nster, Grant/Award Number: MzH 3/020/20; Medical Research Council, Grant/Award Numbers: G1001354, MR/R024790/2; Norges Forskningsr{\aa}d, Grant/Award Numbers: 223273, 249795, 273345, 276082; Swiss National Science Foundation, Grant/Award Numbers: 32003B_135679, 32003B_159780, 324730_192755, CRSK‐3_190185, PZ00P3_193658 Funding information Publisher Copyright: {\textcopyright} 2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.",

year = "2022",

doi = "10.1002/hbm.25837",

language = "English",

journal = "Human Brain Mapping",

issn = "1065-9471",

publisher = "Wiley-Liss Inc.",

}

TY - JOUR

T1 - Mind the gap

T2 - Performance metric evaluation in brain-age prediction

AU - de Lange, Ann Marie G.

AU - Anatürk, Melis

AU - Rokicki, Jaroslav

AU - Han, Laura K.M.

AU - Franke, Katja

AU - Alnæs, Dag

AU - Ebmeier, Klaus P.

AU - Draganski, Bogdan

AU - Kaufmann, Tobias

AU - Westlye, Lars T.

AU - Hahn, Tim

AU - Cole, James H.

N1 - Funding Information: This research was conducted using the UK Biobank under Application 27412. While working on this study, the authors received funding from the Swiss National Science Foundation (Ann‐Marie G. de Lange; PZ00P3_193658; Bogdan Draganski; NCCR Synapsy, project grants Number 32003B_135679, 32003B_159780, 324730_192755 and CRSK‐3_190185), the Leenaards Foundation (Bogdan Draganski), the Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Ageing and Dementia (Melis Anatürk; 5R24AG061421‐03), the UK Medical Research Council (James H. Cole and Melis Anatürk; MR/R024790/2, Klaus P. Ebmeier; G1001354), the HDH Wills 1965 Charitable Trust (Klaus P. Ebmeier; 1117747), the research Council of Norway (Lars T. Westlye; 273345, 249795, 223273; Tobias Kaufmann; 276082), the European Research Council under the European Union's Horizon 2020 research and innovation programme (Lars T. Westlye; 802998), the South‐East Norway Regional Health Authority (Lars T. Westlye; 2015073, 2019107), the German Research Foundation (Katja Franke; FR 3709/1‐2; Tim Hahn; HA7070/2‐2, HA7070/3, HA7070/4), the Interdisciplinary Center for Clinical Research (IZKF) of the medical faculty of Münster (Tim Hahn; MzH 3/020/20), the Interdisciplinary Center for Clinical Research (IZKF) of the Jena University hospital (Katja Franke; AMSP 07) and the ERA‐Net Cofund through the ERA PerMed project “IMPLEMENT” (Jaroslav Rokicki). We thank Dr Dónal Hill, Institute of Physics, École polytechnique fédérale de Lausanne (EPFL), for valuable statistical input. Open access funding enabled and organized by Projekt DEAL. Funding Information: Collaboratory on Research Definitions for Reserve and Resilience in Cognitive Aging and Dementia, Grant/Award Number: 5R24AG061421‐03; Deutsche Forschungsgemeinschaft, Grant/Award Numbers: FR 3709/1‐2, HA7070/2‐2, HA7070/3, HA7070/4; ERA‐net Cofound, Grant/Award Number: ERA PerMed project ”IMPLEMENT”; Fondation Leenaards; H2020 European Research Council, Grant/Award Number: 802998; HDH Wills 1965 Charitable Trust, Grant/Award Number: 1117747; Helse Sør‐Øst RHF, Grant/Award Numbers: 2015073, 2019107; Interdisciplinary Center for Clinical Research of the Jena University hospital, Grant/Award Number: AMSP 07; Interdisciplinary Center for Clinical Research of the Medical Faculty of Münster, Grant/Award Number: MzH 3/020/20; Medical Research Council, Grant/Award Numbers: G1001354, MR/R024790/2; Norges Forskningsråd, Grant/Award Numbers: 223273, 249795, 273345, 276082; Swiss National Science Foundation, Grant/Award Numbers: 32003B_135679, 32003B_159780, 324730_192755, CRSK‐3_190185, PZ00P3_193658 Funding information Publisher Copyright: © 2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.

PY - 2022

Y1 - 2022

N2 - Estimating age based on neuroimaging-derived data has become a popular approach to developing markers for brain integrity and health. While a variety of machine-learning algorithms can provide accurate predictions of age based on brain characteristics, there is significant variation in model accuracy reported across studies. We predicted age in two population-based datasets, and assessed the effects of age range, sample size and age-bias correction on the model performance metrics Pearson's correlation coefficient (r), the coefficient of determination (R2), Root Mean Squared Error (RMSE) and Mean Absolute Error (MAE). The results showed that these metrics vary considerably depending on cohort age range; r and R2 values are lower when measured in samples with a narrower age range. RMSE and MAE are also lower in samples with a narrower age range due to smaller errors/brain age delta values when predictions are closer to the mean age of the group. Across subsets with different age ranges, performance metrics improve with increasing sample size. Performance metrics further vary depending on prediction variance as well as mean age difference between training and test sets, and age-bias corrected metrics indicate high accuracy—also for models showing poor initial performance. In conclusion, performance metrics used for evaluating age prediction models depend on cohort and study-specific data characteristics, and cannot be directly compared across different studies. Since age-bias corrected metrics generally indicate high accuracy, even for poorly performing models, inspection of uncorrected model results provides important information about underlying model attributes such as prediction variance.

AB - Estimating age based on neuroimaging-derived data has become a popular approach to developing markers for brain integrity and health. While a variety of machine-learning algorithms can provide accurate predictions of age based on brain characteristics, there is significant variation in model accuracy reported across studies. We predicted age in two population-based datasets, and assessed the effects of age range, sample size and age-bias correction on the model performance metrics Pearson's correlation coefficient (r), the coefficient of determination (R2), Root Mean Squared Error (RMSE) and Mean Absolute Error (MAE). The results showed that these metrics vary considerably depending on cohort age range; r and R2 values are lower when measured in samples with a narrower age range. RMSE and MAE are also lower in samples with a narrower age range due to smaller errors/brain age delta values when predictions are closer to the mean age of the group. Across subsets with different age ranges, performance metrics improve with increasing sample size. Performance metrics further vary depending on prediction variance as well as mean age difference between training and test sets, and age-bias corrected metrics indicate high accuracy—also for models showing poor initial performance. In conclusion, performance metrics used for evaluating age prediction models depend on cohort and study-specific data characteristics, and cannot be directly compared across different studies. Since age-bias corrected metrics generally indicate high accuracy, even for poorly performing models, inspection of uncorrected model results provides important information about underlying model attributes such as prediction variance.

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JF - Human Brain Mapping

ER -

Mind the gap: Performance metric evaluation in brain-age prediction

Abstract

Bibliographical note

ASJC Scopus Subject Areas

PubMed: MeSH publication types

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