Mechanical Properties of Plasma Immersion Ion Implanted PEEK for Bioactivation of Medical Devices

Autor:	Marcela M.M. Bilek, Giselle C. Yeo, Fariba Dehghani, Dougal G. McCulloch, Ali Fathi, M. Kracica, Anthony S. Weiss, David R. McKenzie, Steven G. Wise, Edgar A. Wakelin
Rok vydání:	2015
Předmět:	Materials science Plasma Gases Nitrogen Polymers Enzyme-Linked Immunosorbent Assay Polyethylene Glycols Benzophenones Polyether ether ketone chemistry.chemical_compound Tropoelastin Tensile Strength Peek Nanotechnology General Materials Science Surface layer Composite material Elastic modulus Mechanical Phenomena Ions chemistry.chemical_classification Photoelectron Spectroscopy Polymer Ketones Nanoindentation Plasma-immersion ion implantation Elasticity Oxygen Immobilized Proteins Equipment and Supplies chemistry Microscopy Electron Scanning Limiting oxygen concentration
Zdroj:	ACS Applied Materials & Interfaces. 7:23029-23040
ISSN:	1944-8252 1944-8244
DOI:	10.1021/acsami.5b06395
Popis:	Plasma immersion ion implantation (PIII) is used to modify the surface properties of polyether ether ketone for biomedical applications. Modifications to the mechanical and chemical properties are characterized as a function of ion fluence (treatment time) to determine the suitability of the treated surfaces for biological applications. Young's modulus and elastic recovery were found to increase with respect to treatment time at the surface from 4.4 to 5.2 MPa and from 0.49 to 0.68, respectively. The mechanical properties varied continuously with depth, forming a graded layer where the mechanical properties returned to untreated values deep within the layer. The treated surface layer exhibited cracking under cyclical loads, associated with an increased modulus due to dehydrogenation and cross-linking; however, it did not show any sign of delamination, indicating that the modified layer is well integrated with the substrate, a critical factor for bioactive surface coatings. The oxygen concentration remained unchanged at the surface; however, in contrast to ion implanted polymers containing only carbon and hydrogen, the oxygen concentration within the treated layer was found to decrease. This effect is attributed to UV exposure and suggests that PIII treatments can modify the surface to far greater depths than previously reported. Protein immobilization on PIII treated surfaces was found to be independent of treatment time, indicating that the surface mechanical properties can be tuned for specific applications without affecting the protein coverage. Our findings on the mechanical properties demonstrate such treatments render PEEK well suited for use in orthopedic implantable devices.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::135669de5803b1b7418d785bdf448825 https://doi.org/10.1021/acsami.5b06395 Zobrazit plný text záznamu