CTSpine1K: A Large-Scale Dataset for Spinal Vertebrae Segmentation in Computed Tomography
- URL: http://arxiv.org/abs/2105.14711v4
- Date: Thu, 03 Oct 2024 09:08:20 GMT
- Title: CTSpine1K: A Large-Scale Dataset for Spinal Vertebrae Segmentation in Computed Tomography
- Authors: Yang Deng, Ce Wang, Yuan Hui, Qian Li, Jun Li, Shiwei Luo, Mengke Sun, Quan Quan, Shuxin Yang, You Hao, Pengbo Liu, Honghu Xiao, Chunpeng Zhao, Xinbao Wu, S. Kevin Zhou,
- Abstract summary: We introduce a large-scale spine CT dataset, called CTSpine1K, curated from multiple sources for vertebra segmentation.
This dataset contains 1,005 CT volumes with over 11,100 labeled vertebrae belonging to different spinal conditions.
- Score: 27.27657839726696
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- Abstract: Spine-related diseases have high morbidity and cause a huge burden of social cost. Spine imaging is an essential tool for noninvasively visualizing and assessing spinal pathology. Segmenting vertebrae in computed tomography (CT) images is the basis of quantitative medical image analysis for clinical diagnosis and surgery planning of spine diseases. Current publicly available annotated datasets on spinal vertebrae are small in size. Due to the lack of a large-scale annotated spine image dataset, the mainstream deep learning-based segmentation methods, which are data-driven, are heavily restricted. In this paper, we introduce a large-scale spine CT dataset, called CTSpine1K, curated from multiple sources for vertebra segmentation, which contains 1,005 CT volumes with over 11,100 labeled vertebrae belonging to different spinal conditions. Based on this dataset, we conduct several spinal vertebrae segmentation experiments to set the first benchmark. We believe that this large-scale dataset will facilitate further research in many spine-related image analysis tasks, including but not limited to vertebrae segmentation, labeling, 3D spine reconstruction from biplanar radiographs, image super-resolution, and enhancement.
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