%0 Journal Article %A Amir Ansari %A Kirubin Pillay %A Luke Baxter %A Emad Arasteh %A Anneleen Dereymaeker %A Gabriela Schmidt Mellado %A Katrien Jansen %A Gunnar Naulaers %A Aomesh Bhatt %A Sabine Van Huffel %A Caroline Hartley %A Maarten De Vos %A Rebeccah Slater %T Brain age as an estimator of neurodevelopmental outcome: A deep learning approach for neonatal cot-side monitoring %D 2023 %R 10.1101/2023.01.24.525361 %J bioRxiv %P 2023.01.24.525361 %X The preterm neonate can experience stressors that affect the rate of brain maturation and lead to long-term neurodevelopmental deficits. However, some neonates who are born early follow normal developmental trajectories. Extraction of data from electroencephalography (EEG) signals can be used to calculate the neonate’s brain age which can be compared to their true age. Discrepancies between true age and brain age (the brain age delta) can then be used to quantify maturational deviation, which has been shown to correlate with long-term abnormal neurodevelopmental outcomes. Nevertheless, current brain age models that are based on traditional analytical techniques are less suited to clinical cot-side monitoring due to their dependency on long-duration EEG recordings, the need to record activity across multiple EEG channels, and the manual calculation of predefined EEG features which is time-consuming and may not fully capture the wealth of information in the EEG signal. In this study, we propose an alternative deep-learning approach to determine brain age, which operates directly on the EEG, using a Convolutional Neural Network (CNN) block based on the Inception architecture (called Sinc). Using this deep-learning approach on a dataset of preterm infants with normal neurodevelopmental outcomes (where we assume brain age = postmenstrual age), we can calculate infant brain age with a Mean Absolute Error (MAE) of 0.78 weeks (equivalent to a brain age estimation error for the infant within +/− 5.5 days of their true age). Importantly, this level of accuracy can be achieved by recording only 20 minutes of EEG activity from a single channel. This compares favourably to the degree of accuracy that can be achieved using traditional methods that require long duration recordings (typically >2 hours of EEG activity) recorded from a higher density 8-electrode montage (MAE = 0.73 weeks). Importantly, the deep learning model’s brain age deltas also distinguish between neonates with normal and severely abnormal outcomes (Normal MAE = 0.71 weeks, severely abnormal MAE = 1.27 weeks, p=0.02, one-way ANOVA), making it highly suited for potential clinical applications. Lastly, in an independent dataset collected at an independent site, we demonstrate the model’s generalisability in age prediction, as accurate age predictions were also observed (MAE of 0.97 weeks).HighlightsPreterm stress exposure leads to long-term neurodevelopmental deficitsDeficits are quantifiable using EEG-based brain age prediction errorsOur deep-learning solution for brain age prediction outperforms previous approachesPredictions are achieved with only 20 mins EEG and a single bipolar channelPrediction errors correlate with long-term Bayley scale neurodevelopmental outcomesCompeting Interest StatementThe authors have declared no competing interest. %U https://www.biorxiv.org/content/biorxiv/early/2023/01/25/2023.01.24.525361.full.pdf