Improving our understanding of metal implant failures: Multiscale chemical imaging of exogenous metals in ex-vivo biological tissues


Biological exposures to micro- and nano-scale exogenous metal particles generated as a consequence of in-service degradation of orthopaedic prosthetics can result in severe adverse tissues reactions. However, individual reactions are highly variable and are not easily predicted, due to in part a lack of understanding of the speciation of the metal-stimuli which dictates cellular interactions and toxicity. Investigating the chemistry of implant derived metallic particles in biological tissue samples is complicated by small feature sizes, low concentrations and often a heterogeneous speciation and distribution. These challenges were addressed by developing a multi-scale two-dimensional X-ray absorption spectroscopic (XAS) mapping approach to discriminate sub-micron changes in particulate chemistry within ex-vivo tissues associated with failed CoCrMo total hip replacements (THRs). As a result, in the context of THRs, we demonstrate much greater variation in Cr chemistry within tissues compared with previous reports. Cr compounds including phosphate, hydroxide, oxide, metal and organic complexes were observed and correlated with Co and Mo distributions. This variability may help explain the lack of agreement between biological responses observed in experimental exposure models and clinical outcomes. The multi-scale 2D XAS mapping approach presents an essential tool in discriminating the chemistry in dilute biological systems where speciation heterogeneity is expected. Significance: Metal implants are routinely used in healthcare but may fail following degradation in the body. Although specific implants can be identified as ‘high-risk’, our analysis of failures is limited by a lack of understanding of the chemistry of implant metals within the peri-prosthetic milieu. A new approach to identify the speciation and variability in speciation at sub-micron resolution, of dilute exogenous metals within biological tissues is reported; applied to understanding the failure of metallic (CoCrMo) total-hip-replacements widely used in orthopedic surgery. Much greater variation in Cr chemistry was observed compared with previous reports and included phosphate, hydroxide, oxide, metal and organic complexes. This variability may explain lack of agreement between biological responses observed in experimental exposure models and clinical outcomes.

Publication DOI:
Divisions: College of Engineering & Physical Sciences > Aston Institute of Materials Research (AIMR)
College of Engineering & Physical Sciences
Additional Information: © 2019 Acta Materialia Inc. Published by Elsevier Ltd. CC BY-NC-ND. Funding: National Institute for Health Research Award NIHR/CS/010/001, Diamond Light Source Studentship, Natural Sciences and Engineering Research Council of Canada (grant No. 2017- 05862).
Uncontrolled Keywords: CoCr chemistry,Metal particle chemistry,Microfocus spectroscopy,Total hip replacement,XANES mapping,XRF,Biotechnology,Biomaterials,Biochemistry,Biomedical Engineering,Molecular Biology
Publication ISSN: 1878-7568
Last Modified: 01 Apr 2024 07:33
Date Deposited: 20 Jun 2019 09:04
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Related URLs: https://linking ... 742706119303988 (Publisher URL)
http://www.scop ... tnerID=8YFLogxK (Scopus URL)
PURE Output Type: Article
Published Date: 2019-10-15
Published Online Date: 2019-06-05
Accepted Date: 2019-05-28
Authors: Morrell, Alexander P.
Floyd, Hayley
W. Mosselmans, J. Frederick
Grover, Liam M.
Castillo-michel, Hiram
Davis, Edward
Parker, Julia E.
Martin, Richard A. (ORCID Profile 0000-0002-6013-2334)
Addison, Owen

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