Research Article
Anticipatory Healthcare Analytics: Inferring Latent Disease Dynamics from Noisy Clinical Observations
Philip de Melo*
Issue:
Volume 12, Issue 1, March 2026
Pages:
1-13
Received:
24 March 2026
Accepted:
7 April 2026
Published:
28 April 2026
DOI:
10.11648/j.jfmhc.20261201.11
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Abstract: Artificial intelligence (AI) in healthcare is predominantly built on observational data that provide incomplete, delayed, and noisy representations of underlying biological processes. Such limitations constrain current predictive models, which often remain reactive and fail to capture the intrinsic dynamics of disease evolution. In this study, we introduce a novel AI-driven framework based on latent-state reconstruction, designed to infer hidden disease trajectories from partial clinical and population-level observations and to generate dynamic, forward-looking risk estimates. The proposed approach departs fundamentally from traditional methods by explicitly modeling healthcare systems as partially observed complex adaptive systems. It reconstructs latent health states that evolve over time and gives rise to observable clinical measurements subject to stochastic variability. Drawing a conceptual parallel to quantum mechanics, where a system’s true state is described by a wave function that governs probabilistic observations, our framework treats the latent health state as the primary object of inference rather than the observed data alone. This shift enables a transition from descriptive analytics to anticipatory intelligence. By deriving hazard functions from reconstructed latent trajectories, the framework provides earlier and more accurate detection of disease progression, outbreak dynamics, and systemic instability. Empirical and theoretical analysis demonstrates that this approach captures underlying population heterogeneity and temporal dynamics that are inaccessible to conventional models. This work establishes a new paradigm for AI in healthcare, where prediction is grounded in the reconstruction of hidden system dynamics, enabling proactive intervention and more reliable decision-making in complex, high-dimensional environments.
Abstract: Artificial intelligence (AI) in healthcare is predominantly built on observational data that provide incomplete, delayed, and noisy representations of underlying biological processes. Such limitations constrain current predictive models, which often remain reactive and fail to capture the intrinsic dynamics of disease evolution. In this study, we i...
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