Polymeric wear debris produced by articulation of the femoral head against
the ultra-high-molecular-weight polyethylene (UHMWPE) socket of a total hip
replacement has been implicated as the main cause of osteolysis and subseq
uent failure of these implants. Potential solutions to this problem are to
employ hard-bearing surface combinations such as metal-on-metal or ceramic-
on-ceramic prostheses. The aim of this study was to investigate the differe
nce in lubrication modes and friction of a range of material combinations u
sing synthetic and biological fluids as the lubricants. The experimental re
sults were compared with theoretical predictions of film thicknesses and lu
brication modes. A strong correlation was observed between experiment and t
heory when employing carboxy methyl cellulose fluids as the lubricant. Unde
r these conditions, the ceramic-on-ceramic joints showed full fluid film lu
brication while the metal-on-metal and metal-on-plastic prostheses operated
under a mixed lubrication regime. With bovine serum as the lubricant in th
e all ceramic joint however, the full fluid film lubrication was inhibited
due to adsorbed proteins. In the metal-on-metal joints, this adsorbed prote
in layer acted to reduce the friction while in the ceramic coupling the fri
ction was increased. The use of bovine serum as the lubricant also signific
antly increased the friction in the metal-on-plastic joint. Therefore, the
simple calculations using non-biological lubricants should not be relied up
on in the design of orthopaedic bearing surfaces. (C) 2000 Elsevier Science
S.A. All rights reserved.