Objective:

Here, we assess whether bio-signatures of brain age captured from MRI in patients with acute post-traumatic headache (aPTH) attributed to mild traumatic brain injury (mTBI) may serve as surrogate neuroimaging biomarker for predicting PTH persistence.

Background:

Deep learning has shown utility for calculating “brain age” using magnetic resonance imaging (MRI) as a proxy indicator of brain integrity. The difference between a person’s brain age and their actual biological age (Δage) indicates whether a person’s brain shows age-related changes.

Design/Methods:

We trained a ResNet-18 model on a cohort of 7,377 HC (public datasets: IXI, ICBM, ABIDE, OASIS, NACC) to predict biological age using T1-weighted brain MRI scans. Our model outperforms other baseline methods with mean absolute error (MAE)=2.56 on held-out HC test set. We applied this trained model to a different HC cohort (N=40, mean age=38.5) and an aPTH cohort (N=37, mean age=42.4). Following mTBI, aPTH patients underwent imaging within 0-59 days.  At three months post-mTBI, 19 patients (mean age=44.8) had headache recovery and at 6 months post-mTBI 20 patients (mean age=42.8) had headache recovery.

Results:

Using baseline imaging, predicted Δage for HC and aPTH patients was -0.6±11.0 and 0.5±9.9 respectively. For aPTH patients who had headache recovery at 3-month follow-up, predicted Δage was 0.5±8.3 and 0.8±11.7 for those without headache recovery. Patients who continued to have headache persistence at 6-month had predicted Δage of 1.3±9.8.

Conclusions: