This study investigated the effects of wear particles, produced from a number of implant materials, at the bone-implant interface using a small animal model.

Particles were prepared from metal, ceramic and polymer replacement joint components or implant grade stock by grinding the materials against a diamond embedded grinding pad. The mean diameter of the particles ranged from 1.5mm to 3.2mm. Sterilised particles were suspended in sterile saline containing 2% v/v male Sprague-Dawley serum at a concentration of 109 particles per ml.

Seventy-two male Sprague-Dawley rats were assigned to twelve groups of six animals. A ceramic pin was inserted into the right tibia of each animal. Six groups were assigned a particle type with one group acting as vehicle control. 100ml of particle suspension or vehicle was injected into each knee joint at 8, 10 and 12 weeks following implantation and the animals were killed 2 weeks later. Of the remaining five groups, four were assigned a particle type and one was the vehicle control. These animals were injected with 100ml of particle suspension or vehicle at 20, 22 and 24 weeks following pin implantation and were killed 2 weeks later. The tibia and femora were removed, disarticulated and processed for histology. The total gap between pin and bone, including fibrous tissue, was measured.

Specimens showed no signs of infection either clinically or in the histopathology. All materials tested produced lesions at the bone-implant interface. A significant difference was seen between metal injected vs. vehicle control animals and aluminium oxide injected vs. vehicle controls. Particles of stainless steel produced the greatest response and this finding may have implications for the use of metal on metal articulations aimed at eliminating polyethylene wear.

This study investigated the relationship between histological, clinical and radiological features of aseptically loose total joint replacements (TJRs) and synovial fluid levels of interleukin (IL)-1b, IL-6, IL-8 and IL-10.

Tissue and synovial fluid samples were retrieved from patients undergoing primary (hip; n=15: knee; n=13), or revision of aseptically loose TJRs (hip; n=14: knee; n=9). The presence of inflammatory cells, blood vessels and wear debris in the tissue were assessed on a relative scale. Revision TJRs were assessed for sepsis, migration of the implant, gross loosening and the degree of radiolucency. Cytokine levels in the synovial fluid samples were determined by ELISA.

All cytokines were increased in synovial fluid from revision TJRs compared to primary replacements, as were the degree of macrophage and giant cell infiltration (p< 0.01). There was a significant positive correlation between the presence of macrophages and giant cells with the levels of IL-1b, IL-8 and IL-10 (p< 0.05) but not IL-6.

The amount of wear debris was related to the presence of macrophages and giant cells (p< 0.01) but not to any of the cytokines.

There were no relationships between any of the clinical parameters and the presence of wear debris or the levels of any cytokine with the exception of IL-6 and gross loosening (p< 0.01). Similarly there were no differences between hips and knees for any of the parameters except IL-6, for which higher levels were found in hips (p< 0.05).

The results suggest that macrophages and giant cells are responsible for the majority of IL-1b, IL-8 and IL-10 production but another cell type is contributing to IL-6 production. Furthermore, IL-6 does not fit the pattern of the other cytokines as it is upregulated in hip joints compared to knees and correlates with the presence of gross loosening. This may suggest a unique role for IL-6 that requires further investigation.