Advanced manufacturing techniques and advancements in biodegradable biomaterials

“…Therefore, suitable mechanical characteristics are essential to achieve the load-carrying ability of orthopedic prostheses. The tensile modulus of prosthesis material must be identical to the modulus of a bone to reduce the effect of stress shielding [ [151] , [152] , [153] , [154] ]. The similarity in modulus of both bone and implant material assists in equal stress distribution.…”

Advances in biodegradable materials: Degradation mechanisms, mechanical properties, and biocompatibility for orthopedic applications

“…Therefore, suitable mechanical characteristics are essential to achieve the load-carrying ability of orthopedic prostheses. The tensile modulus of prosthesis material must be identical to the modulus of a bone to reduce the effect of stress shielding [ [151] , [152] , [153] , [154] ]. The similarity in modulus of both bone and implant material assists in equal stress distribution.…”

Advances in biodegradable materials: Degradation mechanisms, mechanical properties, and biocompatibility for orthopedic applications

“…In order to solve the negative effects of conventional metal INs in long bone fracture repair, the researchers studied the variety of degradable biomaterials in recent years [27][28][29]. However, the demands for unique slender structure of the INs and extremely high mechanical strength are difficult to meet [30][31][32].…”

Magnesium-Containing Silicate Bioceramic Degradable Intramedullary Nail for Bone Fractures

Development and Characterization of Zn–Mg Biodegradable Materials Using Powder Metallurgy