Investigating the Data Addition Dilemma in Longitudinal TBI MRI
Titikhsha, A.; Akhtar, M.; Mollah, A. M.
Show abstract
Clinical machine learning (CML)for brain MRI often assumes that more data guarantees better performance, yet added samples can reduce accuracy when they arise from a different distribution, a phenomenon known as the Data Addition Dilemma. We present a systematic study of this issue in longitudinal TBI MRI, where acute baseline scans (S1) and follow-up scans (S2) differ substantially. Using a 14-subject, 28-scan cohort, we quantify the combined effects of intra-subject session shifts and inter-subject variability on severity classification. We evaluate four training schemes: (1) intra-session upper bound (S1[->]S1), (2) cross-session OOD testing (S1[->]S2), (3) pooled training (S1+S2[->]S1,S2), and (4) LOSO-IPA, which adds one unlabeled S2 scan per patient. With a lightweight logistic-regression model on PCA features, we show that naive pooling can degrade accuracy, pooled training trades baseline performance for modest robustness gains, and LOSOIPA recovers accuracy close to the intra-session limit. We recommend per-subject follow-up anchoring and diagonal CORAL alignment to mitigate session effects. These results clarify when additional data help or hinder CML workflows and provide a minimally invasive strategy for reliable longitudinal TBI severity assessment.
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