Related papers: Learning Patient-Specific Disease Dynamics with Latent Flow Matching for Longitudinal Imaging Generation

Learning Patient-Specific Disease Dynamics with Latent Flow Matching for Longitudinal Imaging Generation

URL: http://arxiv.org/abs/2512.09185v2
Date: Sat, 13 Dec 2025 14:47:19 GMT
Title: Learning Patient-Specific Disease Dynamics with Latent Flow Matching for Longitudinal Imaging Generation
Authors: Hao Chen, Rui Yin, Yifan Chen, Qi Chen, Chao Li,
Abstract summary: Understanding disease progression is a central clinical challenge with implications for early diagnosis and personalized treatment.<n>We propose to treat the disease dynamic as a velocity field and leverage Flow Matching (FM) to align the temporal evolution of patient data.<n>We present $$-LFM, a framework for modeling patient-specific latent progression with flow matching.
Score: 17.33607122354623
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Understanding disease progression is a central clinical challenge with direct implications for early diagnosis and personalized treatment. While recent generative approaches have attempted to model progression, key mismatches remain: disease dynamics are inherently continuous and monotonic, yet latent representations are often scattered, lacking semantic structure, and diffusion-based models disrupt continuity with random denoising process. In this work, we propose to treat the disease dynamic as a velocity field and leverage Flow Matching (FM) to align the temporal evolution of patient data. Unlike prior methods, it captures the intrinsic dynamic of disease, making the progression more interpretable. However, a key challenge remains: in latent space, Auto-Encoders (AEs) do not guarantee alignment across patients or correlation with clinical-severity indicators (e.g., age and disease conditions). To address this, we propose to learn patient-specific latent alignment, which enforces patient trajectories to lie along a specific axis, with magnitude increasing monotonically with disease severity. This leads to a consistent and semantically meaningful latent space. Together, we present $Δ$-LFM, a framework for modeling patient-specific latent progression with flow matching. Across three longitudinal MRI benchmarks, $Δ$-LFM demonstrates strong empirical performance and, more importantly, offers a new framework for interpreting and visualizing disease dynamics.

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