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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
Larson, A. N., Polly, D. W., Sponseller, P. D., Kelly, M. P., Richards, B. S., Garg, S., Parent, S., Shah, S. A., Weinstein, S. L., Crawford, C. H., Sanders, J. O., Blakemore, L. C., Oetgen, M. E., Fletcher, N. D., Kremers, W. K., Marks, M. C., Brearley, A. M., Aubin, C.-É., Sucato, D. J., ... Erickson, M. A. (2024). The Effect of Implant Density on Adolescent Idiopathic Scoliosis Fusion. Journal of Bone and Joint Surgery-American Volume, 106(3), 180-189. Lien externe
La Barbera, L., Larson, A. N., & Aubin, C.-É. (2021). Correction objectives have higher impact than screw pattern and density on the optimal 3D correction of thoracic AIS: a biomechanical study. Spine Deformity, 9(3), 655-664. Disponible
La Barbera, L., Larson, A. N., & Aubin, C.-É. (2021). How do spine instrumentation parameters influence the 3D correction of thoracic adolescent idiopathic scoliosis? A patient-specific biomechanical study. Clinical Biomechanics, 84, 10 pages. Lien externe
La Barbera, L., Larson, A. N., Rawlinson, J., & Aubin, C.-É. (2021). In silico patient-specific optimization of correction strategies for thoracic adolescent idiopathic scoliosis. Clinical Biomechanics, 81, 105200 (11 pages). Lien externe
Larson, A. N., Floccari, L. V., Garg, S., Erickson, M. A., Sponseller, P. D., Brito, J. P., Aubin, C.-É., & Polly, D. W. J. (2020). Willingness to enroll in a surgical randomized controlled trial: patient and parent preferences regarding implant density for adolescent idiopathic scoliosis fusion. Spine Deformity, 8(5), 957-963. Lien externe
La Barbera, L., Larson, A. N., Wang, X., & Aubin, C.-É. (mai 2019). Screw density and pattern have limited impact on the 3D correction of Lenke 1A curves [Communication écrite]. 34eme Congrès de la Recherche des étudiants des cycles supérieurs et des postdoctorants au Centre de recherche du Centre hospitalier universitaire Sainte-Justine, Montréal, Québec, Canada. Non disponible
La Barbera, L., Larson, A. N., Wang, X., & Aubin, C.-É. (avril 2018). Screw density has lower impact than correction objectives on 3D correction of Lenke 1A curves [Communication écrite]. 39e journée de la recherche du Programme d'orthopédie Édouward-Samson (POES) et de la division d'orthopédie de l'Université de Montréal, Montréal, Québec, Canada. Non disponible
Le Navéaux, F., Larson, A. N., Labelle, H., Wang, X., & Aubin, C.-É. (2016). How does implant distribution affect 3D correction and bone-screw forces in thoracic adolescent idiopathic scoliosis spinal instrumentation? Clinical Biomechanics, 39, 25-31. Lien externe
Le Naveaux, F., Aubin, C.-É., Larson, A. N., Polly, D. W., Baghdadi, Y. M. K., & Labelle, H. (2015). Implant Distribution in Surgically Instrumented Lenke 1 Adolescent Idiopathic Scoliosis Does It Affect Curve Correction? Spine, 40(7), 462-468. Lien externe
Le Naveaux, F., Aubin, C.-É., Larson, A. N., Polly, D. W., Baghdadi, Y. M., Labelle, H., & Implants Maximise Outcomes Study Groups, M. (juillet 2013). How does pedicle screw distribution impact curve correction in Lenke 1 curves? [Communication écrite]. 20th International Meeting on Advanced Spine Techniques (IMAST), Vancouver, British Columbia. Lien externe
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
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
Wang, X., Larson, A. N., Polly, D. W. J., & Aubin, C.-É. (2023). Biomechanical Computational Study of Pedicle Screw Position and Density in Adolescent Idiopathic Scoliosis Instrumentation. Spine, 48(20), 1436-1445. Lien externe
Wang, X., Larson, A. N., Labelle, H., Parent, S., Ledonio, C. G. T., Polly, D. W., & Aubin, C.-É. (octobre 2017). Biomechanical comparison of different pedicle screw patterns in adolescent idiopathic scoliosis instrumentation [Communication écrite]. 47e Réunion annuelle de la Société de scoliose du Québec, Baie St-Paul, QC. Non disponible
Wang, X., Larson, A. N., Crandall, D. G., Parent, S., Labelle, H., Ledonio, C. G. T., & Aubin, C.-É. (2017). Biomechanical effect of pedicle screw distribution in AIS instrumentation using a segmental translation technique: computer modeling and simulation. Scoliosis and Spinal Disorders, 12(1). Disponible
Wang, X., Larson, A. N., Labelle, H., Parent, S., Ledonio, C. G. T., Polly, D. W., & Aubin, C.-É. (septembre 2017). Optimization of implant density in AIS instrumentation using a computerized spine simulator [Communication écrite]. 52nd Annual Meeting & Course - Scoliosis Research Society, Philadelphia, PA. Non disponible
Wang, X., Larson, A. N., Crandall, D. G., Parent, S., Labelle, H., Ledonio, C. G. T., & Aubin, C.-É. (octobre 2016). Does variation in pedicle screw pattern affect deformity correction and bone-screw forces in adolescent idiopathic scoliosis instrumentation using polyaxial screws with dorsal height adjustability? [Communication écrite]. 46e Réunion annuelle de la Société de scoliose du Québec, Estérel, QC. Non disponible
Wang, X., Aubin, C.-É., Larson, A. N., Labelle, H., & Parent, S. (juillet 2012). Biomechanical Analysis of Pedicle Screw Density in Spinal Instrumentation for Scoliosis Treatment: First Results. [Communication écrite]. 9th Biennial Meeting of the International Research Society of Spinal Deformities (IRSSD 2012), Poznan, Poland. Lien externe
