TY - JOUR
T1 - Quantification of human bone microarchitecture damage in press-fit femoral knee implantation using HR-pQCT and digital volume correlation
AU - Rapagna, Sophie
AU - Berahmani, Sanaz
AU - Wyers, Caroline E.
AU - van den Bergh, Joop P. W.
AU - Reynolds, Karen J.
AU - Tozzi, Gianluca
AU - Janssen, Dennis
AU - Perilli, Egon
N1 - Funding Information:
This study was partially funded by a research grant by DePuy Synthes Joint Reconstruction (Leeds, UK) . The funding body had no role in the study design, collection, analysis and interpretation of data, writing and decision to submit this article for publication. The authors would like to thank orthopaedic surgeon, Dr. S. van de Groes, for performing the press-fit implantations.
Publisher Copyright:
© 2019 Elsevier Ltd
PY - 2019/9
Y1 - 2019/9
N2 - Primary press-fit fixation of femoral knee prostheses is obtained thanks to the inside dimensions of the implant being undersized with respect to the bone cuts created intra-operatively, dictated by a press-fit specified by the implant design. However, during prostheses press-fit implantation, high compressive and shear stresses at the implant-bone interface are generated, which causes permanent bone damage. The extent of this damage is unknown, but it may influence the implant stability and be a contributing factor to aseptic loosening, a main cause of revisions for knee arthroplasty. The aim of this ex-vivo study was to quantify, using high-resolution peripheral quantitative computed tomography (HR-pQCT) imaging and Digital Volume Correlation (DVC), permanent bone deformation due to press-fit femoral knee implantation of a commonly used implant. Six human cadaveric distal femora were resected and imaged with HR-pQCT (60.7 mu m/voxel, isotropic). Femurs were fitted with cementless femoral knee implants (Sigma PFC) and rescanned after implant removal. For each femur, permanent deformation was examined in the anterior, posterior-medial and posterior-lateral condyles for volumes of interest (VOIs) of 10 mm depth. The bone volume fraction (BV/TV) for the VOIs in pre- and post-implantation images was calculated, at increasing depth from the bone surface. DVC was applied on the VOIs pre- and post-implantation, to assess trabecular bone displacements and plastically accumulated strains. The "BV/TVpost/BV/TVpre ratio vs. depth" showed, consistently among the six femurs, three consecutive points of interest at increasing bone depth, indicating: bone removal (ratio <100%), compaction (ratio > 100%) and no changes (ratio = 100%). Accordingly, the trabecular bone displacement computed by DVC suggested bone compaction up to 2.6 +/- 0.8 mm in depth, with peak third principal strains of -162,100 +/- 55,000 mu epsilon (mean absolute error: 1,000-2,000 mu epsilon, SD: 200-500 mu epsilon), well above the yield strain of bone (7,000-10,000 mu epsilon). Combining 3D-imaging, at spatial resolutions obtainable with clinical HR-pQCT, and DVC, determines the extent of plastic deformation and accumulated compressive strains occurring within the bone due to femoral press-fit implantation. The methods and data presented can be used to compare different implants, implant surface coatings and press-fit values. These can also be used to advance and validate computational models by providing information about the bone-implant interface obtained experimentally. Future studies using these methods can assist in determining the influence of bone damage on implant stability and the subsequent osseointegration.
AB - Primary press-fit fixation of femoral knee prostheses is obtained thanks to the inside dimensions of the implant being undersized with respect to the bone cuts created intra-operatively, dictated by a press-fit specified by the implant design. However, during prostheses press-fit implantation, high compressive and shear stresses at the implant-bone interface are generated, which causes permanent bone damage. The extent of this damage is unknown, but it may influence the implant stability and be a contributing factor to aseptic loosening, a main cause of revisions for knee arthroplasty. The aim of this ex-vivo study was to quantify, using high-resolution peripheral quantitative computed tomography (HR-pQCT) imaging and Digital Volume Correlation (DVC), permanent bone deformation due to press-fit femoral knee implantation of a commonly used implant. Six human cadaveric distal femora were resected and imaged with HR-pQCT (60.7 mu m/voxel, isotropic). Femurs were fitted with cementless femoral knee implants (Sigma PFC) and rescanned after implant removal. For each femur, permanent deformation was examined in the anterior, posterior-medial and posterior-lateral condyles for volumes of interest (VOIs) of 10 mm depth. The bone volume fraction (BV/TV) for the VOIs in pre- and post-implantation images was calculated, at increasing depth from the bone surface. DVC was applied on the VOIs pre- and post-implantation, to assess trabecular bone displacements and plastically accumulated strains. The "BV/TVpost/BV/TVpre ratio vs. depth" showed, consistently among the six femurs, three consecutive points of interest at increasing bone depth, indicating: bone removal (ratio <100%), compaction (ratio > 100%) and no changes (ratio = 100%). Accordingly, the trabecular bone displacement computed by DVC suggested bone compaction up to 2.6 +/- 0.8 mm in depth, with peak third principal strains of -162,100 +/- 55,000 mu epsilon (mean absolute error: 1,000-2,000 mu epsilon, SD: 200-500 mu epsilon), well above the yield strain of bone (7,000-10,000 mu epsilon). Combining 3D-imaging, at spatial resolutions obtainable with clinical HR-pQCT, and DVC, determines the extent of plastic deformation and accumulated compressive strains occurring within the bone due to femoral press-fit implantation. The methods and data presented can be used to compare different implants, implant surface coatings and press-fit values. These can also be used to advance and validate computational models by providing information about the bone-implant interface obtained experimentally. Future studies using these methods can assist in determining the influence of bone damage on implant stability and the subsequent osseointegration.
KW - Press-fit implantation
KW - Uncemented total knee replacement
KW - Trabecular bone deformation
KW - HR-pQCT
KW - Digital volume correlation
KW - TRABECULAR BONE
KW - CANCELLOUS BONE
KW - MICRO-CT
KW - STRAIN
KW - FIXATION
KW - DISPLACEMENT
KW - COMPACTION
U2 - 10.1016/j.jmbbm.2019.04.054
DO - 10.1016/j.jmbbm.2019.04.054
M3 - Article
C2 - 31146201
SN - 1751-6161
VL - 97
SP - 278
EP - 287
JO - Journal of the mechanical behavior of biomedical materials
JF - Journal of the mechanical behavior of biomedical materials
ER -