Explainable Vertebral Fracture Analysis with Uncertainty Estimation Using Differentiable Rule-Based Classification
Paper in proceeding, 2024
We present a novel method for explainable vertebral fracture assessment (XVFA) in low-dose radiographs using deep neural networks, incorporating vertebra detection and keypoint localization with uncertainty estimates. We incorporate Genant's semi-quantitative criteria as a differentiable rule-based means of classifying both vertebra fracture grade and morphology. Unlike previous work, XVFA provides explainable classifications relatable to current clinical methodology, as well as uncertainty estimations, while at the same time surpassing state-of-the art methods with a vertebra-level sensitivity of 93% and end-to-end AUC of 97% in a challenging setting. Moreover, we compare intra-reader agreement with model uncertainty estimates, with model reliability on par with human annotators.
uncertainty quantification
detection
rule-based classification
explainability
morphology
Vertebral fracture assessment
compression
Author
Victor Wåhlstrand
Chalmers, Electrical Engineering, Signal Processing and Biomedical Engineering
Lisa Johansson
University of Gothenburg
Jennifer Alvén
Chalmers, Electrical Engineering, Signal Processing and Biomedical Engineering
Mattias Lorentzon
University of Gothenburg
Ida Haggstrom
University of Gothenburg
Lecture Notes in Computer Science
0302-9743 (ISSN) 16113349 (eISSN)
Vol. 15010 318-328978-3-031-72116-8 (ISBN)
27th International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI)
Marrakesh, Morocco,
Marrakesh, Morocco,
Subject Categories
Clinical Medicine
Medical Engineering
Biological Sciences
DOI
10.1007/978-3-031-72117-5_30