Full-field in vitro measurements and in silico predictions of strain shielding in the implanted femur after total hip arthroplasty

Alterations in bone strain as a result of implantation may contribute towards periprosthetic bone density changes after Total Hip Arthroplasty (THA). Computational models provide full-field strain predictions in implant-bone constructs; however, these predictions should be verified using experimental models wherever possible. In the present work, finite element (FE) predictions of surface strains in intact and implanted composite femurs were verified using digital image correlation (DIC). Relationships were sought between post implantation strain states across seven defined Gruen zones (GZ) and clinically observed longer- term bone density changes. Computational predictions of strain distributions in intact and implanted femurs were compared to DIC measurements in two regions of interest. Regression analyses indicated a strong linear correlation between measurements and predictions (R = 0.927 intact, 0.926 implanted) with low standard error (SE = 38µ? intact, 26µ? implanted). Pre- to postoperative changes in measured and predicted surface strains were found to relate qualitatively to clinically-observed volumetric bone density changes across seven Gruen zones: marked proximal bone density loss corresponded with a 50-64% drop in surface strain, and slight distal density changes corresponded with 4-14% strain increase. These results support the use of DIC as a pre-clinical tool for predicting post implantation strain shielding, indicative of long-term bone adaptations

Size of cup affects the anterior capsular distance in total hip arthroplasty, as measured with ultrasound.

Previously was found that sonography is a reliable method to measure a capsular distance in total hip arthroplasty hips. The aim of our current study was to investigate the relation between the implanted size of the cup and the anterior capsular distance, as measured with ultrasound one year after THA