Osteolysis due to wear debris is a primary cause of failure of total joint replacements. Although debris produced by the joint articulating surfaces has been studied and simulated extensively, fretting wear debris, produced at nonarticulating surfaces, has not received adequate attention. We developed a three-station fretting wear simulator to reproduce in vivo motion and stresses at the interfaces of total joint replacements. The simulator is based on the beam bending theory and is capable of producing cyclic displacement from , under varying magnitudes of contact stresses. The simulator offers three potential advantages over previous studies: The ability to control the displacement by load, the ability to produce very small displacements, and dynamic normal loads as opposed to static. A pilot study was designed to test the functionality of the simulator, and verify that calculated displacements and loads produced the predicted differences between two commonly used porous ingrowth titanium alloy surfaces fretting against cortical bone. After 1.5 million cycles, the simulator functioned as designed, producing greater wear of bone against the rougher plasma-sprayed surface compared to the fiber-mesh surface, as predicted. A novel pin-on-disk apparatus for simulating fretting wear at orthopaedic implant interfaces due to micromotion is introduced. The test parameters measured with the fretting wear simulator were as predicted by design calculations, and were sufficient to measure differences in the height and weight of cortical bone pins rubbing against two porous ingrowth surfaces, plasma-sprayed titanium and titanium fiber mesh.
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June 2005
Technical Papers
Simulation of Fretting Wear at Orthopaedic Implant Interfaces
Edward Ebramzadeh, Ph.D.,
e-mail: ebramzad@usc.edu
Edward Ebramzadeh, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
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Fabrizio Billi, Ph.D.,
Fabrizio Billi, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
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Sophia N. Sangiorgio, M.S.,
Sophia N. Sangiorgio, M.S.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
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Sarah Mattes, M.S.,
Sarah Mattes, M.S.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
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Werner Schmoelz, Ph.D.,
Werner Schmoelz, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
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Lawrence Dorr
Lawrence Dorr
M.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
Search for other works by this author on:
Edward Ebramzadeh, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, Californiae-mail: ebramzad@usc.edu
Fabrizio Billi, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
Sophia N. Sangiorgio, M.S.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
Sarah Mattes, M.S.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
Werner Schmoelz, Ph.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, California
Lawrence Dorr
M.D.
Biomechanics Laboratory of the J. Vernon Luck
, Sr., M.D. Orthopaedic Research Center, Los Angeles Orthopaedic Hospital∕UCLA and The Dorr Arthritis Institute of Centinela Hospital
, Inglewood, CaliforniaJ Biomech Eng. Jun 2005, 127(3): 357-363 (7 pages)
Published Online: January 2, 2005
Article history
Received:
April 25, 2003
Revised:
January 2, 2005
Citation
Ebramzadeh, E., Billi, F., Sangiorgio, S. N., Mattes, S., Schmoelz, W., and Dorr, L. (January 2, 2005). "Simulation of Fretting Wear at Orthopaedic Implant Interfaces." ASME. J Biomech Eng. June 2005; 127(3): 357–363. https://doi.org/10.1115/1.1894121
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