Deep transfer learning of structural magnetic resonance imaging fused with blood parameters improves brain age prediction.
Bingyu RenYingtong WuLiumei HuangZhiguo ZhangBingsheng HuangHuajie ZhangJinting MaBing LiXukun LiuGuangyao WuJian ZhangLiming ShenQiong LiuJiazuan NiPublished in: Human brain mapping (2021)
Machine learning has been applied to neuroimaging data for estimating brain age and capturing early cognitive impairment in neurodegenerative diseases. Blood parameters like neurofilament light chain are associated with aging. In order to improve brain age predictive accuracy, we constructed a model based on both brain structural magnetic resonance imaging (sMRI) and blood parameters. Healthy subjects (n = 93; 37 males; aged 50-85 years) were recruited. A deep learning network was firstly pretrained on a large set of MRI scans (n = 1,481; 659 males; aged 50-85 years) downloaded from multiple open-source datasets, to provide weights on our recruited dataset. Evaluating the network on the recruited dataset resulted in mean absolute error (MAE) of 4.91 years and a high correlation (r = .67, p <.001) against chronological age. The sMRI data were then combined with five blood biochemical indicators including GLU, TG, TC, ApoA1 and ApoB, and 9 dementia-associated biomarkers including ApoE genotype, HCY, NFL, TREM2, Aβ40, Aβ42, T-tau, TIMP1, and VLDLR to construct a bilinear fusion model, which achieved a more accurate prediction of brain age (MAE, 3.96 years; r = .76, p <.001). Notably, the fusion model achieved better improvement in the group of older subjects (70-85 years). Extracted attention maps of the network showed that amygdala, pallidum, and olfactory were effective for age estimation. Mediation analysis further showed that brain structural features and blood parameters provided independent and significant impact. The constructed age prediction model may have promising potential in evaluation of brain health based on MRI and blood parameters.
Keyphrases
- resting state
- magnetic resonance imaging
- white matter
- functional connectivity
- machine learning
- cognitive impairment
- deep learning
- contrast enhanced
- computed tomography
- cerebral ischemia
- healthcare
- public health
- multiple sclerosis
- type diabetes
- mild cognitive impairment
- mental health
- adipose tissue
- magnetic resonance
- electronic health record
- working memory
- cognitive decline
- high fat diet
- diffusion weighted imaging
- artificial intelligence
- high resolution
- mass spectrometry
- metabolic syndrome
- climate change
- risk assessment
- brain injury
- stress induced
- depressive symptoms
- convolutional neural network
- social support