Structural properties of a new design of composite replicate femurs and tibias.

The purpose of this study was to compare the structural properties of a new vs. established design of composite replicate femurs and tibias. The new design has a cortical bone analog consisting of short-glass-fiber-reinforced (SGFR) epoxy, rather than the fiberglass-fabric-reinforced (FFR) epoxy in the currently available design. The hypothesis was that this new cortical bone analog would improve the uniformity of structural properties between specimens, while having mean stiffness values in the range of natural human bones. The composite replicate bones were tested under bending, axial, and torsional loads. In general, the new SGFR bones were significantly less stiff than the FFR bones, although both bone designs reasonably approximated the structural stiffnesses of natural human bones. With the exceptions of the FFR bone axial tests, the highest variability between specimens was 6.1%. The new SGFR bones had similar variability in structural properties when compared to the FFR bones under bending and torsional loading, but had significantly less variability under axial loading. Differences in epiphyseal geometry between the FFR and SGFR bones, and subsequent seating in the testing fixtures, may account for some of the differences in structural properties; axial stiffness was especially dependent on bone alignment. Stiffness variabilities for the composite replicate bones were much smaller than those seen with natural human bones. Axial strain distribution along the proximal-medial SGFR femur had a similar shape to what was observed on natural human femurs by other investigators, but was considerably less stiff in the more proximal locations.

[1]  L. Whiteside,et al.  The effect of axial and torsional loading on strain distribution in the proximal femur as related to cementless total hip arthroplasty. , 1993, Clinical orthopaedics and related research.

[2]  L Cristofolini,et al.  Mechanical validation of whole bone composite femur models. , 1996, Journal of biomechanics.

[3]  M Martens,et al.  The mechanical characteristics of the long bones of the lower extremity in torsional loading. , 1980, Journal of biomechanics.

[4]  M Martens,et al.  Mechanical behaviour of femoral bones in bending loading. , 1986, Journal of biomechanics.

[5]  A. Cappello,et al.  Mechanical validation of whole bone composite tibia models. , 2000, Journal of biomechanics.

[6]  M. Swiontkowski,et al.  Torsion and bending analysis of internal fixation techniques for femoral neck fractures: The role of implant design and bone density , 1987, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[7]  L. Whiteside,et al.  Strain distribution in the proximal femur with flexible composite and metallic femoral components under axial and torsional loads. , 1993, Journal of biomedical materials research.

[8]  R. Narechania,et al.  Circumferential and axial strain in the proximal femur: effect of prosthesis type and position. , 1980, Clinical orthopaedics and related research.

[9]  K. An,et al.  In vitro stability of an unconstrained total elbow prosthesis. Influence of axial loading and joint flexion angle. , 1993, The Journal of arthroplasty.

[10]  D R Pedersen,et al.  A measurement of proximal femur strain with total hip arthroplasty. , 1980, Journal of Biomechanical Engineering.

[11]  A. U. Daniels,et al.  Initial effect of collarless stem stiffness on femoral bone strain. , 1989, The Journal of arthroplasty.