Abstract
Introduction
BAG-S53P4 has similar mechanical properties as cortical bone tissue and can be used as an additive to bone allografts. The aim of this study was to evaluate the effect of adding BAG-S53P4 to chemically treated allografts with controlled grain size distribution.
Methods
Allografts were prepared and chemically cleaned under sterile conditions. 30 samples were mixed with BAG-S53P4 additive (BG) and compared to a control group (CG) with similar grain size distribution and composition in weight. All samples underwent a uniaxial compression test after compaction with a dropped weight apparatus. The yield limit was determined by a uniaxial compression test and density was recorded. The two groups were tested for statistical differences with the student's t-Test.
Results
Adding BAG-S53P4 to the chemically treated allografts with controlled grain size distribution did not affect the yield limit after compaction. No statistically significant difference regarding the yield limit could be found between CG and BG after compaction (p=0.432).). The yield limit yield limit showed an increase of approximately 96% in CG and 93 % in BG, which confirms the importance of impacting bone chips used for load bearing applications like in hip arthroplasty
Conclusions
Adding BAG-S53P4 seems to have a less profound impact on the yield stress limit. In BG particles smaller than 4 mm were substituted with BAG-S53P4. Achieving a high density may not be the major goal for the bone remodeling process as it may actually obstruct new osteocytes from growing into the allograft material. Adding BAG-S53P4 seems to have limited impact on the yield stress limit. From a biomechanical point of view, BAG-S53P4 can be used as a substitute in total hip replacement if access to bone allograft material is limited.
