The integration of biomechanics and 3D printing has revolutionized orthopedic treatments, offering personalized solutions for complex musculoskeletal conditions. Advances in biomechanics and 3D printing in orthopedics have enabled the creation of patient-specific implants, prosthetics, and surgical guides with unmatched precision. Biomechanical analysis helps in understanding joint mechanics, injury mechanisms, and rehabilitation strategies, leading to improved surgical planning and post-operative outcomes. 3D printing technology has further transformed orthopedic care by allowing for the rapid production of customized bone grafts and scaffolds, enhancing tissue regeneration and implant integration. Additionally, the combination of computational modeling with additive manufacturing is paving the way for more durable and biocompatible orthopedic implants. As research continues, these innovations are set to enhance treatment efficiency, reduce complications, and improve the quality of life for patients requiring orthopedic interventions.
Title : The effect of OTC N-acetyl-cysteine on cobaltemia and cobalturia from cobalt-chromium orthopedic implants
Stephen S Tower, University of Alaska Anchorage, United States
Title : A data driven approach to prehabilitation and rehabilitation for hip and knee replacement patients
Diana Hodgins, Dynamic Metrics Ltd, United Kingdom
Title : AI-Driven infrared imaging and telerobotics in orthopedics: Enhancing diagnostics, surgical precision, and postoperative care
Marcos Brioschi, American Academy of Thermology, United States
Title : Revolutionizing orthopedics: The future of biomechanics through artificial intelligence
Moataz Eltoukhy, University of Miami, United States
Title : The etiological diagnosis of torticollis
Ali Al Kaissi, Ilizarov Institute, Austria
Title : Selective denervation for persistent knee pain after total knee arthroplasty: Long-term outcomes
Shaomin Shi, Medical College of Wisconsin, United States