Total hip arthroplasties are known to corrode predominantly at the taper junctions between Cobalt Chromium Molybedenum (CoCrMo) and Titanium (Ti) alloy components. We aimed to understand the modes underlying clinically significant tissue reactions to metals from corroded implants by determining: (1) what type of metal is present in the tissues, (2) which cells contain the metal species and (3) how this compares with results from metal-on-metal (MOM) hip resurfacings (HRs). This study involved periprosthetic tissue from patients that had undergone revision surgery due to adverse reactions to metal debris (ARMD) from dual-taper prostheses consisting of Ti-based alloy stems paired with CoCrMo necks. We used Synchrotron micro X-ray Fluorescence Spectroscopy (µXRF) and micro X-ray Absorption Near Edge Spectroscopy (µXANES) for detection of Co, Cr and Ti, and determination of their oxidation state. Synchrotron radiation has shown that the chromium in tissues is Cr2O3 when derived from corroded CoCrMo/Ti junctions beside the CrPO4 species found when hip implants release CoCrMo nanoparticles from their bearing surfaces (MoM HRs). Presence of Cr2O3 was associated with titanium oxide TiO2. This may be the outcome of the chemical interaction between the two species. Histological examination showed corrosion products present within viable macrophages and in the extracellular connective tissue, Figure 1. Understanding corrosion at taper junctions and the pathogenesis of the biological response is of significant clinical importance. This is the first study to co-register histology and metal distribution maps and to explore the potential synergy effect of CoCrMo with Ti alloy. This study provides guidance for toxicological studies on wear/corrosion particles, how they stimulate the host response and the cellular mechanisms involved in the pathogenesis of ARMD.
We report the first use of synchrotron xray spectroscopy to characterize and compare the chemical form and distribution of metals found in tissues surrounding patients with metal-on-metal hip replacements that failed with (Ultima hips) or without (current generation, large diameter hips) corrosion. The commonest clinical category of failure of metal-on-metal (MOM) hip replacements is “unexplained” and commonly involved a soft tissue inflammatory response. The mechanism of failure of the Ultima MOM total hip replacement includes severe corrosion of the metal stem and was severe enough to be removed from clinical use. Corrosion is not a feature that we have found in the currently used MOM bearings. To better understand the biological response to MOM wear debris we hypothesized that tissue from failed hips with implant corrosion contained a different type of metal species when compared to those without corrosion.Summary
Introduction