Gaussian Process Diffeomorphic Statistical Shape Modelling Outperforms Angle-Based Methods for Assessment of Hip Dysplasia
This work addresses early diagnosis of hip dysplasia for clinicians and patients, offering a semi-automated tool that improves accuracy and saves time compared to manual methods, though it is incremental as it builds on existing statistical shape modeling techniques.
The authors tackled the problem of diagnosing hip dysplasia, a risk factor for osteoarthritis, by developing a Gaussian Process Diffeomorphic Statistical Shape Model (GPDSSM) using CT scans, which achieved an AUC of 96.2% in classification, outperforming angle-based methods at 91.2%.
Dysplasia is a recognised risk factor for osteoarthritis (OA) of the hip, early diagnosis of dysplasia is important to provide opportunities for surgical interventions aimed at reducing the risk of hip OA. We have developed a pipeline for semi-automated classification of dysplasia using volumetric CT scans of patients' hips and a minimal set of clinically annotated landmarks, combining the framework of the Gaussian Process Latent Variable Model with diffeomorphism to create a statistical shape model, which we termed the Gaussian Process Diffeomorphic Statistical Shape Model (GPDSSM). We used 192 CT scans, 100 for model training and 92 for testing. The GPDSSM effectively distinguishes dysplastic samples from controls while also highlighting regions of the underlying surface that show dysplastic variations. As well as improving classification accuracy compared to angle-based methods (AUC 96.2% vs 91.2%), the GPDSSM can save time for clinicians by removing the need to manually measure angles and interpreting 2D scans for possible markers of dysplasia.