A novel hybrid design and modelling of a customised graded Ti-6Al-4V porous hip implant to reduce stress-shielding: An experimental and numerical analysis

Seyed Ataollah Naghavi; Maryam Tamaddon; Pilar Garcia-Souto; Mehran Moazen; Stephen Taylor; Jia Hua; Chaozong Liu

doi:10.3389/fbioe.2023.1092361

A novel hybrid design and modelling of a customised graded Ti-6Al-4V porous hip implant to reduce stress-shielding: An experimental and numerical analysis

Front Bioeng Biotechnol. 2023 Jan 26:11:1092361. doi: 10.3389/fbioe.2023.1092361. eCollection 2023.

Authors

Seyed Ataollah Naghavi¹, Maryam Tamaddon¹, Pilar Garcia-Souto², Mehran Moazen³, Stephen Taylor¹, Jia Hua⁴, Chaozong Liu¹

Affiliations

¹ Institute of Orthopaedics and Musculoskeletal Science, Division of Surgery and Interventional Science, Royal National Orthopaedic Hospital, University College London, Stanmore, United Kingdom.
² Medical Physics and Biomedical Engineering, University College London, London, United Kingdom.
³ Department of Mechanical Engineering, University College London, London, United Kingdom.
⁴ School of Science and Technology, Middlesex University, London, United Kingdom.

Abstract

Stress shielding secondary to bone resorption is one of the main causes of aseptic loosening, which limits the lifespan of hip prostheses and exacerbates revision surgery rates. In order to minimise post-hip replacement stress variations, this investigation proposes a low-stiffness, porous Ti6Al4V hip prosthesis, developed through selective laser melting (SLM). The stress shielding effect and potential bone resorption properties of the porous hip implant were investigated through both in vitro quasi-physiological experimental assays, together with finite element analysis. A solid hip implant was incorporated in this investigation for contrast, as a control group. The stiffness and fatigue properties of both the solid and the porous hip implants were measured through compression tests. The safety factor of the porous hip stem under both static and dynamic loading patterns was obtained through simulation. The porous hip implant was inserted into Sawbone/PMMA cement and was loaded to 2,300 N (compression). The proposed porous hip implant demonstrated a more natural stress distribution, with reduced stress shielding (by 70%) and loss in bone mass (by 60%), when compared to a fully solid hip implant. Solid and porous hip stems had a stiffness of 2.76 kN/mm and 2.15 kN/mm respectively. Considering all daily activities, the porous hip stem had a factor of safety greater than 2. At the 2,300 N load, maximum von Mises stresses on the hip stem were observed as 112 MPa on the medial neck and 290 MPa on the distal restriction point, whereby such values remained below the endurance limit of 3D printed Ti6Al4V (375 MPa). Overall, through the strut thickness optimisation process for a Ti6Al4V porous hip stem, stress shielding and bone resorption can be reduced, therefore proposing a potential replacement for the generic solid implant.

Keywords: additive manufacturing; aseptic loosening; bone resorption; finite element analysis; hip implant; hip stiffness; porous implant; stress shielding.

Grants and funding

This paper was supported by The EU via the H2020-MSCA-RISE-2016 program (734156); Engineering and Physical Sciences Research Council via DTP CASE Programme (Grant No: EP/T517793/1); and Royal Society via an International Exchange program (Grant No: IEC\NSFC\191253).