Anomalous Wear Behavior of UHMWPE During Sliding Against CoCrMo Under Varying Cross-Shear and Contact Pressure

Wear of ultra-high-molecular weight polyethylene (UHMWPE) in joint implant applications has been shown to increase with cross-shear (CS, i.e., multidirectional sliding) but decrease with higher contact pressure (CP). Moreover, structural changes, resulting in protrusions, are known to occur to the s...

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Bibliographic Details
Published inTribology letters Vol. 70; no. 4
Main Authors Dreyer, Michael J., Taylor, William R., Wasmer, Kilian, Imwinkelried, Thomas, Heuberger, Roman, Weisse, Bernhard, Crockett, Rowena
Format Journal Article
LanguageEnglish
Published New York Springer US 01.12.2022
Springer Nature B.V
Subjects
Chemistry and Materials Science
Contact pressure
Corrosion and Coatings
Hardness
Materials Science
Nanotechnology
Original Paper
Physical Chemistry
Plastic deformation
Polyethylene
Secondary ion mass spectrometry
Sliding
Surfaces and Interfaces
Theoretical and Applied Mechanics
Thin Films
Tribology
Ultra high molecular weight polyethylene
Wear
UHMWPE
Wear
Cross-shear
Contact pressure
Pin on disk
Protrusion
Protuberance
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Summary:Wear of ultra-high-molecular weight polyethylene (UHMWPE) in joint implant applications has been shown to increase with cross-shear (CS, i.e., multidirectional sliding) but decrease with higher contact pressure (CP). Moreover, structural changes, resulting in protrusions, are known to occur to the surface of the pin following multidirectional sliding. However, these phenomena are not yet fully understood. In this study, we simultaneously varied CP and CS to derive an empirical formula for the wear factor as a function of these parameters. The wear factor increased when going from unidirectional sliding to multidirectional sliding but decreased with increasing CP, as has been previously observed. Following these tests, the protrusions on the pin surface were chemically and mechanically characterized to gain insights into both their origin and influence on wear behavior. Micro-FT-IR confirmed that the structures consist of polyethylene, rather than adsorbed, denatured proteins. It also allowed the crystallinity of both the protrusions and unaffected UHMWPE to be estimated, showing a strong positive correlation with the hardness of these different areas on the surface. Time-of-flight secondary-ion mass spectrometry was used to probe the chemistry of the surface and near-surface region and indicated the presence of contamination from the test fluid within the structure. This suggests that the protrusions are formed by the folding of UHMWPE following plastic deformation. It is also suggested that the higher hardness of the protrusions affords some protection of the surface, leading to the observed anomalous behavior, whereby wear increases with decreasing CP. Graphical Abstract
ISSN:1023-8883
1573-2711
DOI:10.1007/s11249-022-01660-w