A Proposed Framework for Quantifying AI-to-Clinical Translation: The Algorithm-to-Outcome Concordance (AOC) Metric
Abstract
Background: The rapid evolution of personalized neoantigen vaccines has been accelerated by artificial intelligence (AI)-based prediction models. Yet, a consistent framework to evaluate the translational fidelity between computational predictions and clinical outcomes remains lacking. Methods: This systematic synthesis analyzed six melanoma vaccine trials conducted between 2017 and 2025 across mRNA, peptide, and dendritic cell platforms. We introduced the Algorithm-to-Outcome Concordance (AOC) metric - a quantitative measure linking model performance (AUC) with clinical efficacy (HR/ORR) - and integrated mechanistic, economic, and regulatory perspectives. Results: Simulated AOC values across studies ranged from 0.42-0.79, suggesting heterogeneous concordance between algorithmic prediction and observed outcomes. High tumor mutational burden and clonal neoantigen dominance correlated with improved translational fidelity. Economic modeling suggested that achieving AOC >0.7 could reduce ICER below $100,000/QALY. Conclusions: This framework quantitatively bridges AI-driven neoantigen prediction with clinical translation, offering a reproducible metric for future personalized vaccine validation and regulatory standardization. This study presents AOC as a hypothesis-generating tool, with all computations based on simulated or aggregated trial data for demonstration purposes only.