Abstract
Major long-term complication of total hips is osteolysis in the more active patients. Osteolysis is a result of the biological response to the wear debris particles. This has resulted in the search for improved bearings such as metal and ceramic on polyethylene, all ceramic, and all metal total hips. Wear ranking of metal-polyethylene, ceramic-polyethylene, metal-metal, and ceramic-ceramic total hips has become clear at ratios of 1,000:500:10:1. However, wear debris from polyethylene, ceramic, and metal wear tests average about 0.6, 0.3, and 0.02 microns, respectively. From this information we can now deduce the number of particles librated is millions for ceramics, billions for polyethylene, and trillions for metal.
In recent years, studies have revealed new information on the biological response to various types of wear debris. Factors such as number of particles, particle morphology (size and shape), and surface to volume ratio are becoming keys to a partial comprehension of this biological response and osteolysis. Recent studies have demonstrated that smaller particles (< 0.1 microns) may be more toxic to cells than larger particles (> 0.1 microns). Studies have shown that crosslinking of polyethylene reduces the size of the wear debris particles and that for gamma irradiated polyethylene this reduction in size is proportional to the radiation dose. It has also been shown that crosslinking results in a significant reduction in fibril particles. Therefore, large reductions in wear rate do not necessarily mean that the total joint will be more successful. Thus, two factors, which interact, are the volume rate of wear and the morphology of the wear debris particles. Some investigators have developed a biological ind
The abstracts were prepared by Nico Verdonschot. Correspondence should be addressed to him at Orthopaedic Research Laboratory, University Medical Centre, PO Box 9101, 6500 HB Nijmegen, The Netherlands.
