Acetabular Shell Deformation As A Function Of Shell Stiffness And Bone Strength

Press-fit acetabular shells used for hip replacement rely upon an interference fit with the bone to provide initial stability. This process may result in deformation of the shell. This study aimed to model shell deformation as a process of shell stiffness and bone strength. A cohort of 32 shells with two different wall thicknesses (3 and 4mm) and 10 different shell sizes (44- to 62-mm outer diameter) were implanted into eight cadavers. Shell deformation was then measured in the cadavers using a previously validated ATOS Triple Scan III optical system. The shell-bone interface was then considered as a spring system according to Hooke's law and from this the force exerted on the shell by the bone was calculated using a combined stiffness consisting of the measured shell stiffness and a calculated bone stiffness. The median radial stiffness for the 3-mm wall thickness was 4192N/mm (range, 2920-6257N/mm), while for the 4-mm wall thickness the median was 9633N/mm (range, 6875-14,341N/mm). The median deformation was 48 mu m (range, 3-187 mu m), while the median force was 256N (range, 26-916N). No statistically significant correlation was found between shell stiffness and deformation. Deformation was also found to be not fully symmetric (centres 180 degrees apart), with a median angle discrepancy of 11.5 degrees between the two maximum positive points of deformation. Further work is still required to understand how the bone influences acetabular shell deformation.