Statistical shape model reconstruction with sparse anomalous deformations: Application to intervertebral disc herniation

• Published in: Computerized medical imaging and graphics Vol. 46; pp. 11 - 19
• Main Authors: Neubert, Aleš, Fripp, Jurgen, Engstrom, Craig, Schwarz, Daniel, Weber, Marc-André, Crozier, Stuart
• Format: Journal Article
• Language: English
• Published: United States Elsevier Ltd 01.12.2015
• Subjects: Algorithms; Computer-aided diagnosis; Diagnosis, Computer-Assisted; Herniation; Humans; Image Interpretation, Computer-Assisted - methods; Internal Medicine; Intervertebral disc; Intervertebral Disc - pathology; Intervertebral Disc Displacement - diagnosis; Magnetic Resonance Imaging; Other; ROC Curve; Segmentation; Sparse optimization; Statistical shape model; Statistical shape model; Sparse optimization; Herniation; Segmentation; Magnetic resonance imaging; Intervertebral disc; Computer-aided diagnosis
• ISSN: 0895-6111; 1879-0771
• DOI: 10.1016/j.compmedimag.2015.05.002

•A sparse reconstruction algorithm from statistical shape models is proposed.•The technique allows quantifying morphological anomalies.•Evaluation on intervertebral disc herniation data showed improvements in diagnosis.•The sparse reconstruction can deliver novel quantitative descriptors of pathologies. Many medical image processing techniques rely on accurate shape modeling of anatomical features. The presence of shape abnormalities challenges traditional processing algorithms based on strong morphological priors. In this work, a sparse shape reconstruction from a statistical shape model is presented. It combines the advantages of traditional statistical shape models (defining a ‘normal’ shape space) and previously presented sparse shape composition (providing localized descriptors of anomalies). The algorithm was incorporated into our image segmentation and classification software. Evaluation was performed on simulated and clinical MRI data from 22 sciatica patients with intervertebral disc herniation, containing 35 herniated and 97 normal discs. Moderate to high correlation (R=0.73) was achieved between simulated and detected herniations. The sparse reconstruction provided novel quantitative features describing the herniation morphology and MRI signal appearance in three dimensions (3D). The proposed descriptors of local disc morphology resulted to the 3D segmentation accuracy of 1.07±1.00mm (mean absolute vertex-to-vertex mesh distance over the posterior disc region), and improved the intervertebral disc classification from 0.888 to 0.931 (area under receiver operating curve). The results show that the sparse shape reconstruction may improve computer-aided diagnosis of pathological conditions presenting local morphological alterations, as seen in intervertebral disc herniation.