Effect of neck length on third-generation ceramic head failure; finite element and retrieval analysis

Abstract

BackgroundOptimized design using finite element analysis (FEA) has considerably increased the longevity of ceramic implants in total hip arthroplasty. Unlike previous FEA studies, a 28-mm head with a short neck was found to be prone to failure, even with third-generation ceramic. We conducted a finite element analysis of the third-generation ceramic head failure according to neck lengths and a retrieval analysis of the four fractured ceramic heads. MethodsModels of real specimens were created for short-, medium-, and long-neck heads made of alumina, based on data given by the manufacturer and reverse engineering design. Static loading was simulated in a series of five steps to 46 kN, and fatigue loading consisting of 107 cycles was simulated in walking (4.3 kN) and high-impact (10 kN) conditions to determine the safety factor. ResultsAlthough the maximum principal stress of the long-neck design was the greatest, consistent with a previous FEA study, the safety factor was the lowest at the inner corner between the roof and tapered bore of the ceramic head with the short-neck design in both fatigue-loading conditions. Furthermore, surface analysis of one head revealed that the fracture was propagated from the inner corner between the roof and tapered bore into the base of the ceramic head. ConclusionOur results suggest that the short-neck design with a 28-mm ceramic head has a greater potential risk of ceramic failure than other designs.