IEEE Access (Jan 2023)
A Deep Learning-Based Brain Age Prediction Model for Preterm Infants via Neonatal MRI
Abstract
The accurate, quantitative, and objective prediction of the brain age for premature infants will contribute to the exploration of brain maturity and catch-up growth. Traditional approaches rely heavily on a pediatrician’s clinical experience, which makes the whole process time-consuming and labor-intensive. To solve this problem, we propose a deep learning-based brain age prediction model for preterm infants via neonatal MRI for this purpose, and it is called as BAPNET for short. First of all, we collected a specific dataset including MR images of 281 preterm infants. Then, a pretraining model (DeepBrainNet) is applied as the main backbone, and transfer learning is utilized to enhance the baseline model by making knowledge transfer from the ImageNet dataset. The proposal can be viewed as a specific prediction model by absorbing knowledge enhancement from peripheral visual features. On a test set of 70 preterm infants held out from the original dataset, 2D-BPANET achieved results with an mean square error (MAE) of 1.15 and the 95% - 95% content tolerance interval for a difference (prediction and ground truth) of [−3.82, 3.39], whereas 3D-BPANET achieved better results with an MAE of 1.8 and a difference of [0.51, 3.09]. Meanwhile, we leverage heatmaps to verify the consistency between hindbrain regions and cortical fold regions outputted by our model and the latest studies of brain development in preterm infants. In conclusion, BPANET demonstrates that deep learning can estimate brain maturity in preterm infants and provides a reference standard for preterm infant brain development, which could be applied as a promising tool.
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