Machine learning for automated 3-dimensional segmentation of the spine and suggested placement of pedicle screws based on intraoperative cone-beam computer tomography.
暂无分享,去创建一个
Cristian Lorenz | Michael Grass | Drazenko Babic | Robert Homan | Gustav Burström | Erik Edström | Christian Buerger | Adrian Elmi Terander | John M Racadio | Oscar Persson | M. Grass | C. Lorenz | C. Buerger | R. Nachabe | D. Babic | R. Homan | J. Racadio | Rami Nachabe | Gustav Burström | J. Hoppenbrouwers | Oscar Persson | E. Edström | Adrian Elmi Terander | Jurgen Hoppenbrouwers
[1] Chris A Clark,et al. Semiautomatic tractography: motor pathway segmentation in patients with intracranial vascular malformations. Clinical article. , 2009, Journal of neurosurgery.
[2] F. Cheriet,et al. Global-to-Local Shape Matching for Liver Segmentation in CT Imaging , 2007 .
[3] D. Drazin,et al. Introduction: Intraoperative spinal imaging and navigation. , 2014, Neurosurgical focus.
[4] Tharindu De Silva,et al. Automatic Localization of Target Vertebrae in Spine Surgery: Clinical Evaluation of the LevelCheck Registration Algorithm , 2015, Spine.
[5] S Vidyadhara,et al. Randomized Clinical Study to Compare the Accuracy of Navigated and Non-Navigated Thoracic Pedicle Screws in Deformity Correction Surgeries , 2007, Spine.
[6] Dana H. Ballard,et al. Generalizing the Hough transform to detect arbitrary shapes , 1981, Pattern Recognit..
[7] Horst Bischof,et al. Liver Segmentation in CT Data: A Segmentation Refinement Approach , 2007 .
[8] Laurent Audigé,et al. Worldwide survey on the use of navigation in spine surgery. , 2013, World neurosurgery.
[9] Fengzeng Jian,et al. An improved level set method for vertebra CT image segmentation , 2013, Biomedical engineering online.
[10] R. Härtl,et al. Pedicle screw navigation: a systematic review and meta-analysis of perforation risk for computer-navigated versus freehand insertion. , 2012, Journal of neurosurgery. Spine.
[11] S. Schafer,et al. Automatic localization of vertebral levels in x-ray fluoroscopy using 3D-2D registration: a tool to reduce wrong-site surgery , 2012, Physics in medicine and biology.
[12] Alexander Mason,et al. The accuracy of pedicle screw placement using intraoperative image guidance systems. , 2014, Journal of neurosurgery. Spine.
[13] R. Nachabe,et al. Surgical Navigation Technology Based on Augmented Reality and Integrated 3D Intraoperative Imaging , 2016, Spine.
[14] Seyed-Parsa Hojjat,et al. Micro-computed tomography-based highly automated 3D segmentation of the rat spine for quantitative analysis of metastatic disease. , 2010, Journal of neurosurgery. Spine.
[15] Julien Cohen-Adad,et al. Automatic Segmentation of the Spinal Cord and Spinal Canal Coupled With Vertebral Labeling , 2015, IEEE Transactions on Medical Imaging.
[16] A Uneri,et al. Spinal pedicle screw planning using deformable atlas registration , 2017, Physics in medicine and biology.
[17] Toshifumi Ozaki,et al. Accuracy of pedicle screw insertion in posterior scoliosis surgery: a comparison between intraoperative navigation and preoperative navigation techniques , 2017, European Spine Journal.
[18] Constantin Schizas,et al. Pedicle Screw Placement Accuracy: A Meta-analysis , 2007, Spine.
[19] Jing Zhang,et al. Accuracy of Pedicle Screw Insertion Among 3 Image-Guided Navigation Systems: Systematic Review and Meta-Analysis. , 2018, World neurosurgery.
[20] A Uneri,et al. Registration of MRI to intraoperative radiographs for target localization in spinal interventions , 2017, Physics in medicine and biology.
[21] Nikolaos K. Paschos,et al. Accuracy of pedicle screw placement: a systematic review of prospective in vivo studies comparing free hand, fluoroscopy guidance and navigation techniques , 2012, European Spine Journal.
[22] F. Del Grande,et al. Use of the Airo mobile intraoperative CT system versus the O-arm for transpedicular screw fixation in the thoracic and lumbar spine: a retrospective cohort study of 263 patients. , 2018, Journal of neurosurgery. Spine.
[23] Steven L. Hartmann,et al. Spinal Navigation and Imaging: History, Trends, and Future , 2015, IEEE Transactions on Medical Imaging.
[24] Jacob Cohen. A Coefficient of Agreement for Nominal Scales , 1960 .
[25] Bostjan Likar,et al. A Framework for Automated Spine and Vertebrae Interpolation-Based Detection and Model-Based Segmentation , 2015, IEEE Transactions on Medical Imaging.
[26] Samuel K. Cho,et al. Navigation and Robotics in Spinal Surgery: Where Are We Now? , 2017, Neurosurgery.
[27] Dongsung Kim,et al. A fully automatic vertebra segmentation method using 3D deformable fences , 2009, Comput. Medical Imaging Graph..
[28] Zhi Jin,et al. Modeling and Specifying Parametric Adaptation Mechanism for Self-Adaptive Systems , 2014, APRES.
[29] Olivier Ecabert,et al. Automatic Model-Based Segmentation of the Heart in CT Images , 2008, IEEE Transactions on Medical Imaging.
[30] Drazenko Babic,et al. Spine segmentation from C-arm CT data sets: application to region-of-interest volumes for spinal interventions , 2017, Medical Imaging.
[31] J. Langelaan,et al. Volumetric brain analysis in neurosurgery: Part 1. Particle filter segmentation of brain and cerebrospinal fluid growth dynamics from MRI and CT images. , 2015, Journal of neurosurgery. Pediatrics.
[32] Olivier Ecabert,et al. Optimizing boundary detection via Simulated Search with applications to multi-modal heart segmentation , 2010, Medical Image Anal..
[33] E. Benzel,et al. Clinical outcomes following spinal fusion using an intraoperative computed tomographic 3D imaging system. , 2017, Journal of neurosurgery. Spine.
[34] Michael Söderman,et al. Pedicle Screw Placement Using Augmented Reality Surgical Navigation With Intraoperative 3D Imaging , 2018, Spine.
[35] Cristian Lorenz,et al. Automated model-based vertebra detection, identification, and segmentation in CT images , 2009, Medical Image Anal..