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Get Free AccessBrain-predicted age difference (brain-PAD; brain-predicted age – chronological age) is a potential biomarker for neurodegenerative diseases, including multiple sclerosis (MS). Previous models generally rely on T1-weighted (T1w) MRI brain scans. Here, we developed a deep-learning brain-age prediction model on FLAIR MRI. Our Inception-ResNet-V2 model was more accurate than a current state-of-the-art architecture and the FLAIR based model is comparable to a T1w MRI model. We used saliency maps, showing that areas such as the thalamus and ventricles are salient for brain-age prediction. We applied the FLAIR model to patients with MS, finding significantly higher brain-PAD compared to healthy controls.
Jordan Colman, Olivia Goodkin, Michael A. Foster, Nima Mahmoudi, Mike P. Wattjes, Gabriel González‐Escamilla, Sergiu Groppa, Giuseppe Pontillo, Einar August Høgestøl, Lars T. Westlye, Silvia Messina, Jacqueline Palace, Rosa Cortese, Nicola De Stefano, Àlex Rovira, Jaume Sastre‐Garriga, Stefan Ropele, Maria A. Rocca, Massimo Filippi, Ahmed Toosy, Olga Ciccarelli, Tarek Yousry, Ferrán Prados, Frederik Barkhof, James H. Cole (2023). Adapting and applying the brain age paradigm for clinical imaging in multiple sclerosis (MS). , DOI: https://doi.org/10.58530/2022/1553.
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Type
Article
Year
2023
Authors
25
Datasets
0
Total Files
0
Language
en
DOI
https://doi.org/10.58530/2022/1553
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