Related papers: Accurate Cobb Angle Estimation via SVD-Based Curve Detection and Vertebral Wedging Quantification

Accurate Cobb Angle Estimation via SVD-Based Curve Detection and Vertebral Wedging Quantification

URL: http://arxiv.org/abs/2509.24898v1
Date: Mon, 29 Sep 2025 15:07:55 GMT
Title: Accurate Cobb Angle Estimation via SVD-Based Curve Detection and Vertebral Wedging Quantification
Authors: Chang Shi, Nan Meng, Yipeng Zhuang, Moxin Zhao, Jason Pui Yin Cheung, Hua Huang, Xiuyuan Chen, Cong Nie, Wenting Zhong, Guiqiang Jiang, Yuxin Wei, Jacob Hong Man Yu, Si Chen, Xiaowen Ou, Teng Zhang,
Abstract summary: Adolescent idiopathic scoliosis (AIS) is a common spinal deformity affecting approximately 2.2% of boys and 4.8% of girls worldwide.<n>Traditional methods use simplified spinal models and predetermined curve patterns that fail to address clinical complexity.<n>We present a novel deep learning framework for AIS assessment that simultaneously predicts both superior and inferior endplate angles with corresponding midpoint coordinates for each vertebra.
Score: 15.50536450875717
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Adolescent idiopathic scoliosis (AIS) is a common spinal deformity affecting approximately 2.2% of boys and 4.8% of girls worldwide. The Cobb angle serves as the gold standard for AIS severity assessment, yet traditional manual measurements suffer from significant observer variability, compromising diagnostic accuracy. Despite prior automation attempts, existing methods use simplified spinal models and predetermined curve patterns that fail to address clinical complexity. We present a novel deep learning framework for AIS assessment that simultaneously predicts both superior and inferior endplate angles with corresponding midpoint coordinates for each vertebra, preserving the anatomical reality of vertebral wedging in progressive AIS. Our approach combines an HRNet backbone with Swin-Transformer modules and biomechanically informed constraints for enhanced feature extraction. We employ Singular Value Decomposition (SVD) to analyze angle predictions directly from vertebral morphology, enabling flexible detection of diverse scoliosis patterns without predefined curve assumptions. Using 630 full-spine anteroposterior radiographs from patients aged 10-18 years with rigorous dual-rater annotation, our method achieved 83.45% diagnostic accuracy and 2.55{\deg} mean absolute error. The framework demonstrates exceptional generalization capability on out-of-distribution cases. Additionally, we introduce the Vertebral Wedging Index (VWI), a novel metric quantifying vertebral deformation. Longitudinal analysis revealed VWI's significant prognostic correlation with curve progression while traditional Cobb angles showed no correlation, providing robust support for early AIS detection, personalized treatment planning, and progression monitoring.

Related papers

SG-LRA: Self-Generating Automatic Scoliosis Cobb Angle Measurement with Low-Rank Approximation [38.35450156563293]
We propose a framework including Self-Generation pipeline and Low-Rank Approximation representation (SG-LRA) for automatic Cobb angle measurement. Specifically, we propose a parameterized spine contour representation based on LRA, which enables eigen-spine decomposition and spine contour reconstruction. With our data engine, we generate the largest scoliosis X-ray dataset named Spinal-AI2024 largely without privacy leaks.
arXiv Detail & Related papers (2024-11-19T16:07:58Z)
Deep learning automates Cobb angle measurement compared with multi-expert observers [3.7153471185088427]
The Cobb angle is a widely used scoliosis quantification method that measures the degree of curvature between the tilted vertebrae. We have created fully automated software that precisely measures the Cobb angle and provides clear visualizations of these measurements. This software integrates deep neural network-based spine region detection and segmentation, spine centerline identification, pinpointing the most significantly tilted vertebrae.
arXiv Detail & Related papers (2024-03-18T15:43:45Z)
Shape Matters: Detecting Vertebral Fractures Using Differentiable Point-Based Shape Decoding [51.38395069380457]
Degenerative spinal pathologies are highly prevalent among the elderly population. Timely diagnosis of osteoporotic fractures and other degenerative deformities facilitates proactive measures to mitigate the risk of severe back pain and disability. In this study, we specifically explore the use of shape auto-encoders for vertebrae.
arXiv Detail & Related papers (2023-12-08T18:11:22Z)
HCA-Net: Hierarchical Context Attention Network for Intervertebral Disc Semantic Labeling [3.485615723221064]
We present HCA-Net, a novel contextual attention network architecture for semantic labeling of IVDs. Our approach excels at processing features across different scales and effectively consolidating them to capture the intricate spatial relationships within the spinal cord. In addition, we introduce a skeletal loss term to reinforce the model's geometric dependence on the spine.
arXiv Detail & Related papers (2023-11-21T09:58:39Z)
Predicting Spine Geometry and Scoliosis from DXA Scans [49.68543422441626]
We first train a neural network to predict the middle spine curve in the scan, and then use an integral-based method to determine the curvature along the spine curve. We show that the maximum curvature can be used as a scoring function for ordering the severity of spinal deformation.
arXiv Detail & Related papers (2023-11-15T22:49:08Z)
B-Spine: Learning B-Spline Curve Representation for Robust and Interpretable Spinal Curvature Estimation [50.208310028625284]
We propose B-Spine, a novel deep learning pipeline to learn B-spline curve representation of the spine. We estimate the Cobb angles for spinal curvature estimation from low-quality X-ray images.
arXiv Detail & Related papers (2023-10-14T15:34:57Z)
Automatic diagnosis of knee osteoarthritis severity using Swin transformer [55.01037422579516]
Knee osteoarthritis (KOA) is a widespread condition that can cause chronic pain and stiffness in the knee joint. We propose an automated approach that employs the Swin Transformer to predict the severity of KOA.
arXiv Detail & Related papers (2023-07-10T09:49:30Z)
Semantic Latent Space Regression of Diffusion Autoencoders for Vertebral Fracture Grading [72.45699658852304]
This paper proposes a novel approach to train a generative Diffusion Autoencoder model as an unsupervised feature extractor. We model fracture grading as a continuous regression, which is more reflective of the smooth progression of fractures. Importantly, the generative nature of our method allows us to visualize different grades of a given vertebra, providing interpretability and insight into the features that contribute to automated grading.
arXiv Detail & Related papers (2023-03-21T17:16:01Z)
Learning to diagnose cirrhosis from radiological and histological labels with joint self and weakly-supervised pretraining strategies [62.840338941861134]
We propose to leverage transfer learning from large datasets annotated by radiologists, to predict the histological score available on a small annex dataset. We compare different pretraining methods, namely weakly-supervised and self-supervised ones, to improve the prediction of the cirrhosis. This method outperforms the baseline classification of the METAVIR score, reaching an AUC of 0.84 and a balanced accuracy of 0.75.
arXiv Detail & Related papers (2023-02-16T17:06:23Z)
Scoliosis Detection using Deep Neural Network [0.0]
Scoliosis is a sideways curvature of the spine that most often is diagnosed among young teenagers. Current gold standard to detect and estimate scoliosis is to manually examine the spinal anterior-posterior X-ray images. Deep learning has shown amazing achievements in automatic spinal curvature estimation.
arXiv Detail & Related papers (2022-10-31T12:52:04Z)
Direct Estimation of Spinal Cobb Angles by Structured Multi-Output Regression [42.67503464183464]
The Cobb angle that quantitatively evaluates the spinal curvature plays an important role in the scoliosis diagnosis and treatment. We formulate the estimation of the Cobb angles from spinal X-rays as a multi-output regression task. Our method achieves the direct estimation of Cobb angles with high accuracy, which indicates its great potential in clinical use.
arXiv Detail & Related papers (2020-12-23T12:33:46Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.