Abstract
BackgroundSufficient primary stability is a prerequisite for the clinical success of cementless implants. Therefore, it is important to have an estimation of the primary stability that can be achieved with new stem designs in a pre-clinical trial. Fast assessment of the primary stability is also useful in the preoperative planning of total hip replacements, and to an even larger extent in intraoperatively custom-made prosthesis systems, which result in a wide variety of stem geometries.MethodsAn analytical model is proposed to numerically predict the relative primary stability of cementless hip stems. This analytical approach is based upon the principle of virtual work and a straightforward mechanical model. For five custom-made implant designs, the resistance against axial rotation was assessed through the analytical model as well as through finite element modelling (FEM).ResultsThe analytical approach can be considered as a first attempt to theoretically evaluate the primary stability of hip stems without using FEM, which makes it fast and inexpensive compared to other methods. A reasonable agreement was found in the stability ranking of the stems obtained with both methods. However, due to the simplifying assumptions underlying the analytical model it predicts very rigid stability behaviour: estimated stem rotation was two to three orders of magnitude smaller, compared with the FEM results.ConclusionBased on the results of this study, the analytical model might be useful as a comparative tool for the assessment of the primary stability of cementless hip stems.
Highlights
Sufficient primary stability is a prerequisite for the clinical success of cementless implants
Based on the results of this study, the analytical model might be useful as a comparative tool for the assessment of the primary stability of cementless hip stems
The stability order of the stems resulting from the Finite element (FE) simulations is in fairly good accordance with their ranking based on the antirotation values; RotaMAX exhibits the smallest rotation angles, RotaHIGH is the second most stable stem, closely followed by RotaMED
Summary
Sufficient primary stability is a prerequisite for the clinical success of cementless implants. Fast assessment of the primary stability is useful in the preoperative planning of total hip replacements, and to an even larger extent in intraoperatively custom-made prosthesis systems, which result in a wide variety of stem geometries. Sufficient primary stability is a prerequisite for the long term success of cementless total hip replacements (THRs). A fibrous interface tissue will be formed, which does not give adequate support to the implant This will compromise the endurance of the implant fixation and may lead to aseptic loosening, which is the primary cause of failure in cementless THR [1,3]. It has been suggested to use finite element modelling (FEM) in preoperative planning of THRs [10] to quantify the expected primary stability. The development of such a protocol is far from evident, and it will result in higher costs and longer runtimes
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