Two-stage deep learning for circular landmark detection in hip radiographs.
Journal:
Scientific reports
Published Date:
Jul 16, 2026
Abstract
This study develops a high-resolution anatomical landmark detection method for hip anteroposterior radiographs, designed to enhance the accuracy of femoral head and acetabulum localization in both native and prosthetic joints. A two-stage deep learning framework is introduced that integrates convolutional and Transformer-based architectures. On the global stage, a U-Net estimates coarse landmark positions from downscaled images. These predictions guide the cropping of high-resolution patches, which are subsequently processed in the local stage using a Detection Transformer. Unlike conventional point-based methods, the proposed method models each landmark as a circle and directly regresses its center, radius, and status (natural or prosthetic). On a dataset of 637 annotated hip radiographs, the framework achieved an average center localization error of 1.226 mm (± 1.410) and a radius error of 0.968 mm (± 1.312). Compared with U-Net alone, the two-stage model improved hip center detection accuracy by 22% (p < 0.001), while maintaining robust performance under challenging anatomical conditions, such as osteoarthritis and surgical alterations. These results demonstrate that the proposed two-stage framework provides consistent performance improvements over single-stage approaches. This method enables reliable and precise localization of key hip landmarks, supporting clinical tasks such as surgical planning, implant evaluation, wear assessment, and longitudinal monitoring in orthopedic imaging.
Authors
Keywords
No keywords available for this article.