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Aubin, C.-É., Cobetto, N., Clin, J., Desbiens-Blais, F., Labelle, H., Le May, S., & Parent, S. (juin 2014). Improved brace design combining CAD/CAM and finite element simulation for the conservative treatment of adolescent idiopathic scoliosis (AIS): preliminary results of a randomized control trial [Résumé]. 10th Meeting of the International Research Society of Spinal Deformities (IRSSD 2014), Sapporo, Japon. Publié dans Scoliosis and Spinal Disorders, 10(S1). Disponible
Cobetto, N., Aubin, C.-É., & Parent, S. (2020). Anterior Vertebral Body Growth Modulation: Assessment of the 2-year Predictive Capability of a Patient-specific Finite-element Planning Tool and of the Growth Modulation Biomechanics. Spine, 45(18), E1203-E1209. 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
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. (2017). Planification chirurgicale pour la correction 3D de la scoliose pédiatrique progressive à l'aide d'un dispositif sans fusion flexible [Thèse de doctorat, École Polytechnique de Montréal]. Disponible
Cobetto, N., Aubin, C.-É., Parent, S., Barchi, S., Turgeon, I., & Labelle, H. (2017). 3D correction of AIS in braces designed using CAD/CAM and FEM: a randomized controlled trial. Scoliosis and Spinal Disorders, 12(1). Disponible
Cobetto, N., Aubin, C.-É., Parent, S., Barchi, S., Turgeon, I., & Labelle, H. (mai 2016). Assessment of a brace design approach combining CAD/CAM and numerical modeling for the brace treatment of adolescent idiopathic scoliosis [Communication écrite]. 13th International Conference on Conservative Management of Spinal Deformities and First Joint Meeting of the International Research Society on Spinal Deformities and the Society on Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT-IRSSD 2016), Banff, Alberta (43 pages). Publié dans Scoliosis and Spinal Disorders, 12(S1). Disponible
Cobetto, N., Aubin, C.-É., Parent, S., Clin, J., Barchi, S., Turgeon, I., & Labelle, H. (2016). Effectiveness of braces designed using computer-aided design and manufacturing (CAD/CAM) and finite element simulation compared to CAD/CAM only for the conservative treatment of adolescent idiopathic scoliosis: a prospective randomized controlled trial. European Spine Journal, 25(10), 3056-3064. Disponible
Cobetto, N., Aubin, C.-É., Clin, J., Le May, S., Desbiens-Blais, F., Labelle, H., & Parent, S. (2014). Braces optimized with computer-assisted design and simulations are lighter, more comfortable, and more efficient than plaster-cast braces for the treatment of adolescent idiopathic scoliosis. Spine Deformity, 2(4), 276-284. Disponible
Cobetto, N. (2013). Développement d'une méthode de conception des corsets pour améliorer le confort et l'efficacité du traitement de la scoliose idiopathique [Mémoire de maîtrise, École Polytechnique de Montréal]. Disponible
Duarte, M. P., Aubin, C.-É., Cobetto, N., Roy-Beaudry, M., Bellefleur, C., Turgeon, I., Labelle, H., Guy, A., Barchi, S., & Parent, S. (2022). 3D Radiological Outcomes and Quality of Life of Patients with Moderate Idiopathic Scoliosis Treated with Anterior Vertebral Growth Modulation vs Bracing: 2-Year Follow-up. Spine, 47(15), 1063-1070. Lien externe
Guy, A., Labelle, H., Barchi, S., Audet-Duchesne, É., Cobetto, N., Parent, S., Raison, M., & Aubin, C.-É. (2021). Braces Designed Using CAD/CAM Combined or Not With Finite Element Modeling Lead to Effective Treatment and Quality of Life After 2 Years : A Randomized Controlled Trial. Spine, 46(1), 9-16. Disponible
Martin, S., Cobetto, N., Larson, A. N., & Aubin, C.-É. (2023). Biomechanical modeling and assessment of lumbar vertebral body tethering configurations. Spine Deformity, 11(5), 1041-1048. Lien externe
Parent, S., Duarte, M. P., Aubin, C.-É., Cobetto, N., Roy-Beaudry, M., Bellefleur, C., Turgeon, I., Labelle, H., & Barchi, S. (octobre 2021). 3D radiological outcomes for patients with moderate idiopathic scoliosis curves treated with internal (anterior vertebral growth modulation) vs external bracing: 2 years observational study [Résumé]. EUROSPINE 2021, Vienna, Austria (1 page). Publié dans Brain and Spine, 1(S1). Disponible
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
Raballand, C., Cobetto, N., Larson, A. N., & Aubin, C.-É. (2022). Prediction of post-operative adding-on or compensatory lumbar curve correction after anterior vertebral body tethering. Spine Deformity, 11(1), 27-33. Lien externe
Sattout, A., Clin, J., Cobetto, N., Labelle, H., & Aubin, C.-É. (2016). Biomechanical Assessment of Providence Nighttime Brace for the Treatment of Adolescent Idiopathic Scoliosis. Spine Deformity, 4(4), 253-260. Lien externe
Wang, M., Zhao, S., Shi, C., Guyot, M.-C., Liao, M., Tauer, J. T., Willie, B. M., Cobetto, N., Aubin, C.-É., Küster-Schöck, E. D., Drapeau, P., Zhang, J., Wu, N., & Kibar, Z. (2024). Planar cell polarity zebrafish models of congenital scoliosis reveal novel underlying defects in notochord morphogenesis. Development. Lien externe