Innovative approach to design a new osseointegrated implant for transfemoral amputees with better resistance to fractures. Transfemoral amputees fitted with an osseointegrated implant are experiencing numerous valuable benefits compare to their previous method conventional attachment. However, 40% of them present an early loosening of the implant or ruptures of the abutment. These problems are related to the load regime acting on the fixation system during post-operative rehabilitation and daily ....Innovative approach to design a new osseointegrated implant for transfemoral amputees with better resistance to fractures. Transfemoral amputees fitted with an osseointegrated implant are experiencing numerous valuable benefits compare to their previous method conventional attachment. However, 40% of them present an early loosening of the implant or ruptures of the abutment. These problems are related to the load regime acting on the fixation system during post-operative rehabilitation and daily life activities. In this project, the direct measurement of the actual load applied on the abutment during:
· the load bearing exercises is essential to refine the post- operative rehabilitation program.
· every-day activities is crucial to improve the design and
testing of the implants and abutments.Read moreRead less
Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the dev ....Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the development of reliable, well-controlled manufacturing techniques for tissue engineering scaffolds, revolutionising current scaffold manufacturing practices. It will enhance existing collaborations between the University of Melbourne and the Bernard O'Brien Institute of Microsurgery.Read moreRead less