Computer Science > Computer Vision and Pattern Recognition
arXiv:2603.09359 (cs)
[Submitted on 10 Mar 2026]
Title:Evidential Perfusion Physics-Informed Neural Networks with Residual Uncertainty Quantification
Authors:Junhyeok Lee, Minseo Choi, Han Jang, Young Hun Jeon, Heeseong Eum, Joon Jang, Chul-Ho Sohn, Kyu Sung Choi
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Abstract:Physics-informed neural networks (PINNs) have shown promise in addressing the ill-posed deconvolution problem in computed tomography perfusion (CTP) imaging for acute ischemic stroke assessment. However, existing PINN-based approaches remain deterministic and do not quantify uncertainty associated with violations of physics constraints, limiting reliability assessment. We propose Evidential Perfusion Physics-Informed Neural Networks (EPPINN), a framework that integrates evidential deep learning with physics-informed modeling to enable uncertainty-aware perfusion parameter estimation. EPPINN models arterial input, tissue concentration, and perfusion parameters using coordinate-based networks, and places a Normal--Inverse--Gamma distribution over the physics residual to characterize voxel-wise aleatoric and epistemic uncertainty in physics consistency without requiring Bayesian sampling or ensemble inference. The framework further incorporates physiologically constrained parameterization and stabilization strategies to promote robust per-case optimization. We evaluate EPPINN on digital phantom data, the ISLES 2018 benchmark, and a clinical cohort. On the evaluated datasets, EPPINN achieves lower normalized mean absolute error than classical deconvolution and PINN baselines, particularly under sparse temporal sampling and low signal-to-noise conditions, while providing conservative uncertainty estimates with high empirical coverage. On clinical data, EPPINN attains the highest voxel-level and case-level infarct-core detection sensitivity. These results suggest that evidential physics-informed learning can improve both accuracy and reliability of CTP analysis for time-critical stroke assessment.
| Subjects: | Computer Vision and Pattern Recognition (cs.CV) |
| Cite as: | arXiv:2603.09359 [cs.CV] |
| (or arXiv:2603.09359v1 [cs.CV] for this version) | |
| https://doi.org/10.48550/arXiv.2603.09359
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View a PDF of the paper titled Evidential Perfusion Physics-Informed Neural Networks with Residual Uncertainty Quantification, by Junhyeok Lee and 7 other authors
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