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Optimising brain age estimation through transfer learning: A suite of pre‐trained foundation models for improved performance and generalisability in a clinical setting
by
Booth, Thomas C.
, Hammam, Ahmed
, Guilhem, Emily
, Mazumder, Asif
, Barker, Gareth J.
, Wood, David A.
, Ourselin, Sebastien
, Kafiabadi, Sina
, Townend, Matthew
, Wei, Yiran
, Sasieni, Peter
, Cole, James H.
, Al Busaidi, Ayisha
in
Adolescent
/ Adult
/ Age
/ Age determination
/ Aged
/ Aged, 80 and over
/ Availability
/ Biomarkers
/ Brain
/ Brain - diagnostic imaging
/ brain age
/ Brain research
/ Child, Preschool
/ Chronology
/ Datasets
/ Deep learning
/ Diffusion
/ Disease
/ foundation model
/ Humans
/ Machine Learning
/ Magnetic resonance imaging
/ Medical imaging
/ Mental Recall
/ Middle Aged
/ MRI
/ Neuroimaging
/ Patients
/ Training
/ Transfer learning
/ Young Adult
2024
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Optimising brain age estimation through transfer learning: A suite of pre‐trained foundation models for improved performance and generalisability in a clinical setting
by
Booth, Thomas C.
, Hammam, Ahmed
, Guilhem, Emily
, Mazumder, Asif
, Barker, Gareth J.
, Wood, David A.
, Ourselin, Sebastien
, Kafiabadi, Sina
, Townend, Matthew
, Wei, Yiran
, Sasieni, Peter
, Cole, James H.
, Al Busaidi, Ayisha
in
Adolescent
/ Adult
/ Age
/ Age determination
/ Aged
/ Aged, 80 and over
/ Availability
/ Biomarkers
/ Brain
/ Brain - diagnostic imaging
/ brain age
/ Brain research
/ Child, Preschool
/ Chronology
/ Datasets
/ Deep learning
/ Diffusion
/ Disease
/ foundation model
/ Humans
/ Machine Learning
/ Magnetic resonance imaging
/ Medical imaging
/ Mental Recall
/ Middle Aged
/ MRI
/ Neuroimaging
/ Patients
/ Training
/ Transfer learning
/ Young Adult
2024
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Optimising brain age estimation through transfer learning: A suite of pre‐trained foundation models for improved performance and generalisability in a clinical setting
by
Booth, Thomas C.
, Hammam, Ahmed
, Guilhem, Emily
, Mazumder, Asif
, Barker, Gareth J.
, Wood, David A.
, Ourselin, Sebastien
, Kafiabadi, Sina
, Townend, Matthew
, Wei, Yiran
, Sasieni, Peter
, Cole, James H.
, Al Busaidi, Ayisha
in
Adolescent
/ Adult
/ Age
/ Age determination
/ Aged
/ Aged, 80 and over
/ Availability
/ Biomarkers
/ Brain
/ Brain - diagnostic imaging
/ brain age
/ Brain research
/ Child, Preschool
/ Chronology
/ Datasets
/ Deep learning
/ Diffusion
/ Disease
/ foundation model
/ Humans
/ Machine Learning
/ Magnetic resonance imaging
/ Medical imaging
/ Mental Recall
/ Middle Aged
/ MRI
/ Neuroimaging
/ Patients
/ Training
/ Transfer learning
/ Young Adult
2024
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Optimising brain age estimation through transfer learning: A suite of pre‐trained foundation models for improved performance and generalisability in a clinical setting
Journal Article
Optimising brain age estimation through transfer learning: A suite of pre‐trained foundation models for improved performance and generalisability in a clinical setting
2024
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Overview
Estimated age from brain MRI data has emerged as a promising biomarker of neurological health. However, the absence of large, diverse, and clinically representative training datasets, along with the complexity of managing heterogeneous MRI data, presents significant barriers to the development of accurate and generalisable models appropriate for clinical use. Here, we present a deep learning framework trained on routine clinical data (N up to 18,890, age range 18–96 years). We trained five separate models for accurate brain age prediction (all with mean absolute error ≤4.0 years, R2 ≥ .86) across five different MRI sequences (T2‐weighted, T2‐FLAIR, T1‐weighted, diffusion‐weighted, and gradient‐recalled echo T2*‐weighted). Our trained models offer dual functionality. First, they have the potential to be directly employed on clinical data. Second, they can be used as foundation models for further refinement to accommodate a range of other MRI sequences (and therefore a range of clinical scenarios which employ such sequences). This adaptation process, enabled by transfer learning, proved effective in our study across a range of MRI sequences and scan orientations, including those which differed considerably from the original training datasets. Crucially, our findings suggest that this approach remains viable even with limited data availability (as low as N = 25 for fine‐tuning), thus broadening the application of brain age estimation to more diverse clinical contexts and patient populations. By making these models publicly available, we aim to provide the scientific community with a versatile toolkit, promoting further research in brain age prediction and related areas. Leveraging transfer learning, we introduce a deep learning framework trained on vast clinical MRI data to predict brain age with high accuracy across five MRI sequences. Our versatile, open‐source models, effective even with limited data, promote wider application in diverse clinical scenarios and advance brain age research.
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