Abstract
The surgical treatment of injuries to the spine often requires the placement of pedicle screws. To prevent damage to nearby blood vessels and nerves, the individual vertebrae and their surrounding tissue must be precisely localized. To aid surgical planning in this context we present a clinically applicable geometric flow based method to segment the human spinal column from computed tomography (CT) scans. We first apply anisotropic diffusion and flux computation to mitigate the effects of region inhomogeneities and partial volume effects at vertebral boundaries in such data. The first pipeline of our segmentation approach uses a region-based geometric flow, requires only a single manually identified seed point to initiate, and runs efficiently on a multi-core central processing unit (CPU). A shape-prior formulation is employed in a separate second pipeline to segment individual vertebrae, using both region and boundary based terms to augment the initial segmentation. We validate our method on four different clinical databases, each of which has a distinct intensity distribution. Our approach obviates the need for manual segmentation, significantly reduces inter- and intra-observer differences, runs in times compatible with use in a clinical workflow, achieves Dice scores that are comparable to the state of the art, and yields precise vertebral surfaces that are well within the acceptable 2 mm mark for surgical interventions.
Highlights
Surgical treatment is required for many spine-related conditions including spinal tumours, herniated discs, scoliosis, spinal stenosis, injuries to the cranio-cervical junction and osteoporosis
We show that it is possible to achieve close to state-of-the-art results for spine segmentation from computed tomography (CT) images, as well as for segmentations of individual vertebrae, with a limited number of labelled vertebrae to build the shape prior
We report volume and surface based metrics using the Dice score, Average Symmetric Surface Distance (ASSD), Average Surface Distance (ASD), and Hausdorff Distance 95th percentile (HD95)
Summary
Surgical treatment is required for many spine-related conditions including spinal tumours, herniated discs, scoliosis, spinal stenosis, injuries to the cranio-cervical junction and osteoporosis. These surgical procedures often require the placement of pedicle screws and rods to provide better mechanical stability when adjacent vertebrae must be fused. A mal-positioned screw can have severe neurological (Mac-Thiong et al, 2013), vascular or mechanical ramifications. Screw diameter errors or slight deviations in orientation can cause medial and inferior cortical perforation leading to nerve damage. Pedicle wall fractures associated with cortical perforations decrease screw fixation strength. Length errors can be critical; a screw that is too long may injure the vessels anteriorly and a screw
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