A rolling-gliding wear simulator for the investigation of tribological material pairings for application in total knee arthroplasty


Autoria(s): Richter, B.I.; Ostermeier, S.; Turger, Anke; Denkena, Berend; Hurschler, C.
Data(s)

2010

Resumo

Background: Material wear testing is an important technique in the development and evaluation of materials for use in implant for total knee arthroplasty. Since a knee joint induces a complex rolling-gliding movement, standardised material wear testing devices such as Pin-on-Disc or Ring-on-Disc testers are suitable to only a limited extent because they generate pure gliding motion only.Methods: A rolling-gliding wear simulator was thus designed, constructed and implemented, which simulates and reproduces the rolling-gliding movement and loading of the knee joint on specimens of simplified geometry. The technical concept was to run a base-plate, representing the tibia plateau, against a pivoted cylindrical counter-body, representing one femur condyle under an axial load. A rolling movement occurs as a result of the friction and pure gliding is induced by limiting the rotation of the cylindrical counter-body. The set up also enables simplified specimens handling and removal for gravimetrical wear measurements. Long-term wear tests and gravimetrical wear measurements were carried out on the well known material pairings: cobalt chrome-polyethylene, ceramic-polyethylene and ceramic-ceramic, over three million motion cycles to allow material comparisons to be made.Results: The observed differences in wear rates between cobalt-chrome on polyethylene and ceramic on polyethylene pairings were similar to the differences of published data for existing material-pairings. Test results on ceramic-ceramic pairings of different frontal-plane geometry and surface roughness displayed low wear rates and no fracture failures.Conclusions: The presented set up is able to simulate the rolling-gliding movement of the knee joint, is easy to use, and requires a minimum of user intervention or monitoring. It is suitable for long-term testing, and therefore a useful tool for the investigation of new and promising materials which are of interest for application in knee joint replacement implants. © 2010 Richter et al; licensee BioMed Central Ltd.

Identificador

http://dx.doi.org/10.15488/548

http://www.repo.uni-hannover.de/handle/123456789/572

Idioma(s)

eng

Publicador

London : BioMed Central Ltd.

Relação

http://dx.doi.org/10.1186/1475-925X-9-24

ISSN:1475-925X

Direitos

CC-BY 2.0

https://creativecommons.org/licenses/by/2.0/

frei zugänglich

Fonte

BioMedical Engineering Online 9 (2010)

Palavras-Chave #Knee joint #Knee joint replacement #Material wear #Motion cycle #Pin on disc #Plane geometry #Promising materials #Ring-on-disc #Rolling movement #Test results #Total knee arthroplasty #User intervention #Wear measurements #Wear rates #Wear simulators #Wear test #Cobalt #Joint prostheses #Joints (anatomy) #Materials testing #Polyethylenes #Surface roughness #Surgery #Thermoplastics #Ceramic materials #cobalt #polyethylene #article #biological model #ceramics #femur #instrumentation #knee arthroplasty #materials testing #methodology #motion #surface property #tibia #Arthroplasty, Replacement, Knee #Ceramics #Cobalt #Femur #Materials Testing #Models, Biological #Motion #Polyethylene #Surface Properties #Tibia #ddc:600 #ddc:610 #ddc:570
Tipo

status-type:publishedVersion

doc-type:article

doc-type:Text