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dc.contributor.authorAl-Tamimi, Abdulsalam Abdulaziz
dc.contributor.authorHernandez, Miguel A.
dc.contributor.authorOmar, Abdalla
dc.contributor.authorMorales-Aldana, David Felipe
dc.contributor.authorPeach, Chris
dc.contributor.authorBartolo, Paulo; email: paulojorge.dasilvabartolo@manchester.ac.uk
dc.date.accessioned2021-07-06T15:14:43Z
dc.date.available2021-07-06T15:14:43Z
dc.date.issued2020-07-06
dc.date.submitted2019-10-30
dc.identifierhttps://chesterrep.openrepository.com/bitstream/handle/10034/625153/170_2020_Article_5676.pdf?sequence=2
dc.identifierhttps://chesterrep.openrepository.com/bitstream/handle/10034/625153/170_2020_Article_5676_nlm.xml?sequence=3
dc.identifier.citationThe International Journal of Advanced Manufacturing Technology, volume 109, issue 3-4, page 673-688
dc.identifier.urihttp://hdl.handle.net/10034/625153
dc.descriptionFrom Springer Nature via Jisc Publications Router
dc.descriptionHistory: received 2019-10-30, accepted 2020-06-22, registration 2020-06-22, pub-print 2020-07, pub-electronic 2020-07-06, online 2020-07-06
dc.descriptionPublication status: Published
dc.descriptionFunder: University of Manchester
dc.description.abstractAbstract: Commercially available fixation plates are built using metallic biocompatible materials such as titanium and its alloys and stainless steel. However, these plates show a stiffness mismatch comparing to bone, leading to stress shielding and bone loss. In this paper, we investigate the combined use of topology optimisation and additive manufacturing to print fixation plates with reduced stiffness and improved biological performance. Ti-6Al-4 V plates were topology optimised considering different loading conditions and volume reductions and printed using electron beam melting and selective laser melting. The effect of processing conditions on the mechanical properties, microhardness, wear resistance and surface roughness was analysed. Results show acceptable wear resistance values for a medical device and a reduction of stress shielding by increasing volume reduction. It is also shown that no polishing is required as 3D printed plates are able to support cell attachment and proliferation. In comparison to commercial plates, 3D printed ones show significantly better biological performance. For the same design, SLM plates present higher mechanical properties, while EBM plates present better cell attachment and proliferation.
dc.languageen
dc.publisherSpringer London
dc.rightsLicence for this article: http://creativecommons.org/licenses/by/4.0/
dc.sourcepissn: 0268-3768
dc.sourceeissn: 1433-3015
dc.subjectOriginal Article
dc.subjectAdditive manufacturing
dc.subjectElectron beam melting
dc.subjectFixation plates
dc.subjectSelective laser melting
dc.subjectStress shielding
dc.subjectTopology optimisation
dc.titleMechanical, biological and tribological behaviour of fixation plates 3D printed by electron beam and selective laser melting
dc.typearticle
dc.date.updated2021-07-06T15:14:43Z
dc.date.accepted2020-06-22


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