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Delikaris, A., Wang, X., Boyer, L., Larson, A. N., Ledonio, C. G. T., & Aubin, C.-É. (2018). Implant density at the apex is more important than overall implant density for 3D correction in thoracic adolescent idiopathic scoliosis using rod derotation and en bloc vertebral derotation technique. Spine, 43(11), E639-E647. Lien externe
Boyer, L., Shen, J., Parent, S., Kadoury, S., & Aubin, C.-É. (2018). Accuracy and precision of seven radiography-based measurement methods of vertebral axial rotation in adolescent idiopathic scoliosis. Spine Deformity, 6(4), 351-357. Lien externe
Aubin, C.-É., Clin, J., & Rawlinson, J. (2018). Biomechanical simulations of costo-vertebral and anterior vertebral body tethers for the fusionless treatment of pediatric scoliosis. Journal of Orthopaedic Research, 36(1), 254-264. Lien externe
Benoit, D., Aubin, C.-É., Wang, X., & Crandall, D. G. (novembre 2018). Biomechanical analysis of surgical instrumentation for adult sagittal imbalance with pedicle subtraction osteotomy [Communication écrite]. 48e Réunion annuelle de la Société de scoliose du Québec, Bromont, Québec, Canada. Non disponible
Boyer, L., Shen, J., Parent, S., Kadoury, S., & Aubin, C.-É. (2018). Accuracy and precision of seven radiography-based measurement methods of vertebral axial rotation in adolescent idiopathic scoliosis. Spine Deformity, 6(4), 351-357. Lien externe
Cobetto, N., Aubin, C.-É., & Parent, S. (2018). Surgical Planning and Follow-up of Anterior Vertebral Body Growth Modulation in Pediatric Idiopathic Scoliosis Using a Patient-Specific Finite Element Model Integrating Growth Modulation. Spine Deformity, 6(4), 344-350. Lien externe
Cobetto, N., Parent, S., & Aubin, C.-É. (2018). 3D correction over 2 years with anterior vertebral body growth modulation: A finite element analysis of screw positioning, cable tensioning and postoperative functional activities. Clinical Biomechanics, 51, 26-33. Lien externe
Delikaris, A., Wang, X., Boyer, L., Larson, A. N., Ledonio, C. G. T., & Aubin, C.-É. (2018). Implant density at the apex is more important than overall implant density for 3D correction in thoracic adolescent idiopathic scoliosis using rod derotation and en bloc vertebral derotation technique. Spine, 43(11), E639-E647. Lien externe
Dupuis, S., Fortin, C., Caouette, C., Leclair, I., & Aubin, C.-É. (2018). Global postural re-education in pediatric idiopathic scoliosis: a biomechanical modeling and analysis of curve reduction during active and assisted self-correction. BMC Musculoskeletal Disorders, 19(1). Disponible
Fradet, L., Wang, X., Crandall, D., & Aubin, C.-É. (2018). Biomechanical Analysis of Acute Proximal Junctional Failure After Surgical Instrumentation of Adult Spinal Deformity: The Impact of Proximal Implant Type, Osteotomy Procedures, and Lumbar Lordosis Restoration. Spine Deformity, 6(5), 483-491. Lien externe
Henao, J., Labelle, H., Arnoux, P.-J., & Aubin, C.-É. (2018). Biomechanical simulation of stresses and strains exerted on the spinal cord and nerves during scoliosis correction maneuvers. Spine Deformity, 6(1), 12-19. Lien externe
Lopez Poncelas, M., Aubin, C.-É., Wang, X., & Crandall, D. G. (novembre 2018). Biomechanical Analysis of Proximal Junctional Failure for Different Proximal Fixations of the Spine [Communication écrite]. 48e Réunion annuelle de la Société de scoliose du Québec, Bromont, Québec, Canada. Non disponible
Mustafy, T., Arnoux, P.-J., Benoit, A., Bianco, R.-J., Aubin, C.-É., & Villemure, I. (2018). Load-sharing biomechanics at the thoracolumbar junction under dynamic loadings are modified by anatomical features in adolescent and pediatric vs adult functional spinal units. Journal of the Mechanical Behavior of Biomedical Materials, 88, 78-91. Lien externe
Pea, R., Dansereau, J., Caouette, C., Cobetto, N., & Aubin, C.-É. (2018). Computer-assisted design and finite element simulation of braces for the treatment of adolescent idiopathic scoliosis using a coronal plane radiograph and surface topography. Clinical Biomechanics, 54, 86-91. Lien externe
Sterba, M., Arnoux, P. J., Labelle, H., Warner, W. C., & Aubin, C.-É. (2018). Biomechanical analysis of spino-pelvic postural configurations in spondylolysis subjected to various sport-related dynamic loading conditions. European Spine Journal, 27(8), 2044-2052. Lien externe
Wang, X., Aubin, C.-É., & Rawlinson, J. (2018). Cross-link Torsional Stability for Posterior Fixation in Spinal Fusion Surgery – Phase 1. (Rapport technique). Non disponible
Wang, X., Aubin, C.-É., & Rawlinson, J. (2018). Dual Construct in Adult Spinal Instrumentation Phase 1 – Biomechanical Analysis. (Rapport technique). Non disponible
Wang, X., Aubin, C.-É., & Rawlinson, J. (2018). Multi-rod Constructs Biomechanical Analysis Phase 1: Characterization of Load Sharing. (Rapport technique). Non disponible
Wang, X., Aubin, C.-É., & Rawlinson, J. (2018). Multi-rod Constructs Biomechanical Analysis Phase 2: Characterization of Load Sharing in Adult Instrumentation Involving PSO. (Rapport technique). Non disponible
Wang, X., Yeung, K., Cheung, J. P. Y., Lau, J. Y.-N., Qi, W., Cheung, K. M.-C., & Aubin, C.-É. (juin 2018). A novel scoliosis instrumentation using special superelastic nickel-titanium shape memory alloy spinal rods can result in equivalent correction as conventional rods but with less stress at bone-implant interface: a biomechanical evaluation through simulations [Résumé]. International Research Society of Spinal Deformities (IRSSD) 2018 Meeting, Utrecht, Netherlands. Publié dans Scoliosis and Spinal Disorders, 13(8). Lien externe
Wang, X., Yeung, K., Cheung, J. P. Y., Yiu-Nam Lau, J., Qi, W., Man-Chee Cheung, K., & Aubin, C.-É. (novembre 2018). A novel scoliosis instrumentation using superelastic nickel-titanium shape memory alloy rods : a biomechanical analysis [Communication écrite]. 48e Réunion annuelle de la Société de scoliose du Québec, Bromont, Québec, Canada. Non disponible
