DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS

Boyd A, Rodzen K, Morton M, et al. DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS. Orthop Procs. 2021;103-B(SUPP_16):23-23. doi:10.1302/1358-992X.2021.16.023

Boyd, Adrian, et al. “DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS.” Orthopaedic Proceedings, vol. 103-B, no. SUPP_16, 2021, pp. 23-23., https://doi.org/10.1302/1358-992X.2021.16.023

Boyd, A., Rodzen, K., Morton, M., Acheson, J., McIlhagger, A., Morgan, R., Tormey, D., Dave, F., Sherlock, R., & Meenan, B. (2021). DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS. Orthopaedic Proceedings, 103-B(SUPP_16), 23-23. https://doi.org/10.1302/1358-992X.2021.16.023

Boyd, A., Rodzen, K., Morton, M., Acheson, J., McIlhagger, A., Morgan, R. et al. (2021) “DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS.” Orthopaedic Proceedings, 103-B(SUPP_16), pp. 23-23. Available at: https://doi.org/10.1302/1358-992X.2021.16.023

Boyd, Adrian, Krzysztof Rodzen, Mary Morton, Jonathan Acheson, Alistair McIlhagger, Rheinallt Morgan, David Tormey, Foram Dave, Richard Sherlock, and Brian Meenan. “DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS.” Orthopaedic Proceedings 103-B, no. SUPP_16 (2021): 23-23. https://doi.org/10.1302/1358-992X.2021.16.023

Boyd A, Rodzen K, Morton M, Acheson J, McIlhagger A, Morgan R, et al. DIRECT 3D PRINTING OF POLYETHERETHERKETONE/HYDROXYAPATITE COMPOSITE MATERIALS FOR ORTHOPAEDIC APPLICATIONS. Orthop Procs. 2021 Dec 1;103-B(SUPP_16):23-23. https://doi.org/10.1302/1358-992X.2021.16.023

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Abstract

INTRODUCTION

Polyetheretherketone (PEEK) is a high-performance thermoplastic polymer which has found increasing application in orthopaedic implant devices and has a lot of promise for ‘made-to-measure’ implants produced through additive manufacturing [1]. However, a key limitation of PEEK is that it is bioinert and there is a requirement to functionalise its surface to make the material osteoconductive to ensure a more rapid, improved and stable fixation, in vivo. One approach to solving this issue is to modify PEEK with bioactive materials, such as hydroxyapatite (HA).

OBJECTIVE

To 3D PEEK/HA composite materials using a Fused Filament Fabrication (FFF) approach to enhance the properties of the PEEK matrix.

METHODS

PEEK/HA composites (0–30% w/w HA/PEEK) were 3D printed using a modified Ultimaker 2+ 3D printer. The mechanical, thermal, physical, chemical and in vitro properties of the 3D printed samples were all studied as part of this work.

RESULTS

The CT images of both the filament and the 3D printed samples showed that the HA material was evenly dispersed throughout the bulk all the samples. SEM/EDX measurements highlighted that HA was homogenously distributed across the surface. As the HA content of the samples increases, so does the tensile modulus, ranging from 4.2 GPa (PEEK) to 6.1 GPa (30% HA/PEEK) and are significantly higher than datasheet information of injected molded PEEK samples. All materials supported the growth of osteoblast cells on their surface.

CONCLUSIONS

The results clearly show that we can successfully and easily 3D print HA/PEEK composite materials up to 30% w/w HA/PEEK. The samples produced have a homogeneous distribution of HA in both the bulk and surface of all the samples, and their mechanical performance of the PEEK is enhanced by the addition of HA.