Purpose: Several studies have shown elevated levels of metal ions in the blood of patients with metal-on-metal (MM) total hip arthroplasty (THA). Even though there is no conclusive evidence that the elevated levels of ions have any detrimental effects on the patients, the presence of these ions is still a cause of concerns. The potential of metal ions released from MM implants for oxidative stress is unknown. In the present study, we measured the concentrations of oxidative stress markers in the plasma of patients with MM THAs.

Method: Blood from patients having MM THAs was collected up to 10 years post-operatively into Sarstedt Li-Heparin tubes. Plasma was prepared by centrifugation at 500 × g for 10 min. Plasma was chosen as opposed to whole blood because it is known that the assays for oxidative stress are not recommended for blood and can lead to erroneous data. Total antioxidant levels were measured by the Oxford Biomedical total antioxidant power assay to obtain an overview of the defense capacity of patients against oxidative stress. The activity of catalase and glutathione peroxidase, two antioxidant enzymes acting on specific reactive oxygen species, was measured by enzymatic assays. Peroxide concentrations were measured by the Biomedica Oxy-Stat assay to quantify damage to lipids in the systemic circulation. Nitrototyrosine levels were quantified using the BIOXYTECH® Nitrotyrosine-EIA assay to measure damage to proteins. Levels in patients without prostheses were used as control.

Results: There were no statistical differences in the concentrations of total antioxidants, lipid peroxides, and nitrotyrosines throughout the period of study. The activity of catalase and glutathione peroxidase was also stable over time. Moreover, there was no correlation between the concentrations of these markers and the concentrations of both cobalt and chromium ions.

Conclusion: Metal ions have the potential to induce the production of reactive oxygen species (free radicals) and cause oxidative stress in the plasma of patients with MM THAs. The present study showed that there were no changes in the levels of oxidative stress markers or antioxidant enzymes in these patients up to 10 years post-operatively. Taken together, the data strongly suggest that metal ions may not cause a significant oxidative stress in patients with MM THAs.

Metal particles and ions are liberated from the articular interface of metal-metal (MM) total hip arthroplasties. To better understand their cellular effect, we analyzed the internalization of these metal particles and ions by macrophages in vitro. Macrophages were exposed to metal particles isolated from MM prostheses cycled in a hip simulator and to metal ions. Cells were processed for transmission electron microscopy analysis. Results reveal the internalization of metal particles and Cr³⁺ ions in specifically localized cytoplasmic areas. This study is the first to reveal that metal particles of clinically relevant size and Cr³⁺ ions are internalized by an apparently active process.

In order to minimize articular interface wear, metal-metal (MM) hip implants have been considered as an alternative to conventional metal-polyethylene bearings. While the local histological effects of the metallic particles and ions appear to be similar to that seen with metal-polyethylene hip replacements (i.e., a foreign-body macrophage response), little is known about the cellular effects of these metal particles and ions.

The purpose of this study was to better understand the cellular effect of metal particles and ions, we analyzed their internalization by macrophages in vitro.

J774 mouse macrophages were exposed to metal particles isolated from serum of MM prostheses cycled in a hip simulator and to Cr³⁺ (CrCl₃) and Co²⁺ (CoCl₂) ions. Cells were then processed for transmission electron microscopy analysis.

Micrographs revealed the internalization of metal particles and Cr³⁺ ions in specifically localized cytoplasmic areas, suggesting that they are phagocytosed via an active pathway. Energy disperse X-ray analysis spectra of macrophages incubated with Cr³⁺ revealed a chromium phosphate composition. The same structure and composition were also observed when Cr³⁺ ions were incubated in culture medium without cells, suggesting that they were formed outside the cells. Co²⁺ ions did not form visibly agglomerated structures.

This study is the first to reveal that metal particles of clinically relevant size are internalized by an apparently active process and that Cr³⁺ ions can be internalized by macrophages after binding to phosphorus or phosphoproteins. Kinetic studies are now necessary to better understand the mechanism of phagocytosis and the ultimate outcome of these particles and ions in macrophages.

Purpose: One of the major concerns regarding metal-on-metal prostheses is the biological and biochemical activities of chromium (Cr) ions. Previous studies showed that Cr3+ ions form nanostructures in cell culture media and to date, there has been little attempt to understand the nature of implant-derived metal ions in adjacent tissues or in biofluid. The aim of this work was to determine the nature of proteins present in serum involved in the formation of Cr nanostuctures

Methods: RPMI 1640 and DMEM media supplemented with 5% human serum (HS) or 5% foetal bovine serum (FBS) were incubated for 1h at 37°C in the presence of 50 ppm of Cr3+ (CrCl3). Structures were then isolated and separated by SDS-PAGE. Proteins were stained by Coomassie blue and analyzed by liquid chromatography-quadrupole-time of flight-mass spectrometer (LC-Q-Tof-MS). Data were submitted to Mascot software for a search against the NCBI nonredundant database

Results: Results show that Cr-nanostructures can interact with proteins from both human and bovine serums. On SDS-PAGE, the molecular weights of the proteins were between 40 to 90 kDa. The LC-Q-Tof-MS results suggest that Cr-nanostructures are the result of the interaction with numerous proteins present in serum. However, the complete analysis of results demonstrates that only two proteins (in both RPMI and DMEM) are implicated in these nanostructures: albumin and trans-ferrin. For both proteins, at least 40 peptides matched to the complete sequence of the proteins. The ion scores (“peptide identity score”) were between 79 and 108. Ion scores > 45 indicate identity or extensive homology

Conclusions: Human serum contains more than 400 different proteins. Albumin, the major protein of human serum, has been shown to play a scavenger role by binding and transporting injected and ingested Cr. Albumin could also play an immunological role by addressing signals to defense cells, such as macrophages. Trans-ferrin, known as an iron-carrying protein, also plays a scavenger role for Cr. This suggests that the binding of Cr to these proteins may protect cells from the cytotoxic effect of Cr ions. However, the relation with Cr nano-structures in vivo remains to be determined