Summary. Particulate wear debris with different chemical composition induced similar periprosthetic tissue reactions in patients with loosened uncemented and cemented titanium hip implants, which suggests that osteolysis can develop independent of particle composition. Introduction. Periprosthetic osteolysis is a serious long-term complication in total hip replacements (THR). Wear debris-induced inflammation is thought to be the main cause for periprosthetic bone loss and implant loosening. The aim of the present study was to compare the tissue reactions and wear debris characteristics in periprosthetic tissues from patients with failed uncemented (UC) and cemented (C) titanium alloy hip prostheses. We hypothesised that implant wear products around two different hip designs induced periprosthetic inflammation leading to osteolysis. Patients & Methods. Thirty THR-patients undergoing revision surgery were included: Fifteen patients had loose cemented titanium stems (Titan. ®. , DePuy) and 15 had well-fixed uncemented titanium stems (Profile, DePuy), but loose or worn uncemented metal-backed cups with conventional UHMWPE liners (Gemini, Tropic and Tri-Lock Plus, DePuy; Harris/Galante and Trilogy, Zimmer). A semi-quantitative histological evaluation was performed in 59 sections of periprosthetic tissues using light microscopy. Wear particles were counted by polarised light and high resolution dark-field microscopy. Additionally, particle composition was determined by SEM-EDXA following particle isolation using an enzymatic digestion method. Blood metal ions were determined with high resolution-ICP-MS. Results. The implants in the uncemented group were revised after a median of 15.7 years (range: 7.25–19.3) due to osteolysis and high wear of the polyethylene liner and metal backing resulting in gross metallosis, and/or cup loosening. The average lifetime of implants in the cemented group was only 6.5 years (range: 1.5–11.75) due to early stem loosening with large osteolysis pockets in the femur close to the cement mantle. Tissue examination revealed similar results for both groups: numerous mononuclear histiocytes and chronic inflammatory cells, a few neutrophils and multinucleated giant cells, and to some extent necrosis. The amount of metal particles per histiocyte positively correlated with the tissue reactions in the cemented, but not in the uncemented group. A higher particle load (medians: C: 14727 vs. UC: 1382 particles/mm. 2. , p<0.0001) was found in tissues adjacent to cemented stems, which contained mainly submicron ZrO. 2. particles. Particles containing pure Ti or Ti alloy elements (size range: 0.21 to 6.46 µm) were most abundant in tissues from the uncemented group. Here, also PE was more frequent, but accounted only for a small portion of total particles (2.8 PE/mm. 2. ). The blood concentrations of titanium (range: 3.8–138.5 microgram/L) and zirconium (cemented cases, range: 0.6–3.5 microgram/L) were highly elevated in cases with high abrasive wear and metallosis. Discussion/Conclusion. Phagocytosis of different wear particles by histiocytes induced a similar chronic inflammatory reaction in the periprosthetic tissues in both groups. ZrO. 2. particles, originating from bone cement degradation, dominated in the cemented group, while in the uncemented group the high abundance of pure Ti and Ti alloy particles of various sizes indicates wear of the metal-backed cups. The low density of polyethylene particles in the tissues suggests that they are not solely responsible for the tissue reactions and accompanying osteolysis. Our findings suggest that the chemical composition of wear particles plays a minor role in the mechanism of osteolysis. Particle size, load and ionic exposure might be more important

We analysed revised Mathys isoelastic polyacetal femoral stems with stainless-steel heads and polyethylene acetabular cups from eight patients in order to differentiate various types of particle of wear debris. Loosening of isoelastic femoral stems is associated with the formation of polyacetal wear particles as well as those of polyethylene and metal. All three types of particle were isolated simultaneously by tissue digestion followed by sucrose gradient centrifugation. Polyacetal particles were either elongated, ranging from 10 to 150 μm in size, or shred-like and up to 100 μm in size. Polyethylene particles were elongated or granules, and were typically submicron or micronsized. Polyacetal and polyethylene polymer particles were differentiated by the presence of BaSO. 4. , which is added as a radiopaque agent to polyacetal but not to polyethylene. This was easily detectable by back-scattered SEM analysis and verified by energy dispersive x-ray analysis. Two types of foreign-body giant cell (FBGC) were recognised in the histological specimens. Extremely large FBGCs with irregular polygonal particles showing an uneven, spotty birefringence in polarised light were ascribed to polyacetal debris. Smaller FBGCs with slender elongated particles shining uniformly brightly in polarisation were related to polyethylene. Mononucleated histiocytes containing both types of particle were also present. Our findings offer a better understanding of the processes involved in the loosening of polyacetal stems and indicate why the idea of ‘isoelasticity’ proved to be unsuccessful in clinical practice

The pathogenesis of aseptic loosening of total joint prostheses is not clearly understood. Two features are associated with loosened prostheses, namely, particulate debris and movement of the implant. While numerous studies have evaluated the cellular response to particulate biomaterials, few have investigated the influence of movement of the implant on the biological response to particles. Our aim was therefore to test the hypothesis that excessive mechanical stimulation of the periprosthetic tissues induces an inflammatory response and that the addition of particulate biomaterials intensifies this. We allocated 66 adult Beagle dogs to four groups as follows: stable implants with (I) and without (II) particulate polymethylmethacrylate (PMMA) and moving implants with (III) and without (IV) particulate PMMA. They were then evaluated at 2, 4, 6, 12 and 24 weeks. The stable implants were well tolerated and a thin, fibrous membrane of connective tissue was observed. There was evidence of positive staining in some cells for interleukin-6 (IL-6). Addition of particulate PMMA around the stable implants resulted in an increase in the fibroblastic response and positive staining for IL-6 and tumour necrosis factor-alpha (TNF-α). By contrast, movement of the implant resulted in an immediate inflammatory response characterised by large numbers of histiocytes and cytokine staining for IL-1ß, TNF-α and IL-6. Introduction of particulate PMMA aggravated this response. Animals with particulate PMMA and movement of the implant have an intense inflammatory response associated with accelerated bone loss. Our results indicate that the initiation of the inflammatory response to biomaterial particles was much slower than that to gross mechanical instability. Furthermore, when there was both particulate debris and movement, there was an amplification of the adverse tissue response as evidenced by the presence of osteolysis and increases in the presence of inflammatory cells and their associated cytokines

We used a biodegradable mesh to convert an acetabular defect into a contained defect in six patients at total hip replacement. Their mean age was 61 years (46 to 69). The mean follow-up was 32 months (19 to 50). Before clinical use, the strength retention and hydrolytic in vitro degradation properties of the implants were studied in the laboratory over a two-year period. A successful clinical outcome was determined by the radiological findings and the Harris hip score.

All the patients had a satisfactory outcome and no mechanical failures or other complications were observed. No protrusion of any of the impacted grafts was observed beyond the mesh. According to our preliminary laboratory and clinical results the biodegradable mesh is suitable for augmenting uncontained acetabular defects in which the primary stability of the implanted acetabular component is provided by the host bone. In the case of defects of the acetabular floor this new application provides a safe method of preventing graft material from protruding excessively into the pelvis and the mesh seems to tolerate bone-impaction grafting in selected patients with primary and revision total hip replacement.

A retrospective series of 45 cases of chronic osteomyelitis collected over a period of 14 years was histologically classified into tuberculous osteomyelitis (25) and chronic non-granulomatous osteomyelitis (20). The tuberculous osteomyelitis group was divided into three subgroups: a) typical granulomas (13 cases); b) ill-defined granulomas (seven cases), and c) suspected granulomas (five cases). An in-house polymerase chain reaction amplifying the 245 bp nucleotide sequence, and capable of detecting 10 fg of DNA of Mycobacterium tuberculosis, was used on the DNA extracted from the paraffin blocks. The polymerase chain reaction was positive in 72% of cases (18) of tuberculous osteomyelitis, but when typical cases of tuberculous osteomyelitis with confirmed granulomas were considered (13), this increased to 84.6% (11). The chronic non-granulomatous osteomyelitis group gave positive polymerase chain reaction results in 20% of the cases (4).

Our preliminary study on tuberculous osteomyelitis shows that the polymerase chain reaction can be a very useful diagnostic tool, since a good correlation was seen between typical granulomas and polymerase chain reaction with a sensitivity of 84.6% and a specificity of 80%. In addition, our study shows that tuberculous osteomyelitis can be diagnosed in formalin-fixed paraffin-embedded tissues in the absence of typical granulomas.