Mechanical performance and bioactivation of 3D-printed PEEK for high-performance implant manufacture: a review

Polyetheretherketone (PEEK) has stood out as the leading high-performance thermoplastic for the replacement of metals in orthopaedic, trauma and spinal implant applications due to its high biocompatibility and mechanical properties. Despite its potential for custom-made medical devices, 3D-printed PEEK's mechanical performance depends on processing parameters and its bioinertness may hinder bone opposition to the implant. Concerning these challenges, this review focuses on the available literature addressing the improvement of the mechanical performance of PEEK processed through fused filament fabrication (FFF) along with literature on bioactivation of PEEK for improved osseointegration. The reviewed research suggests that improvements can be achieved in mechanical performance of 3D-printed PEEK with adequate FFF parametrization while different bioactivation techniques can be used to improve the bioperformance of 3D-printed PEEK. The adequate approaches towards these procedures can increase PEEK's potential for the manufacture of high-performance custom-made implantable devices that display improved bone-implant integration and prevent stress shielding of the treated bone. [GRAPHICS]

Automated summary

Polyetheretherketone (PEEK) is a high-performance thermoplastic that stands out for its biocompatibility and mechanical properties, making it a preferred choice for replacing metals in medical applications. However, the mechanical performance of 3D-printed PEEK depends on processing parameters and its bioinertness may hinder bone integration. This review focuses on improving the mechanical performance of 3D-printed PEEK through fused filament fabrication (FFF) and enhancing its bioactivity for better osseointegration.