% IMPORTANT: The following is UTF-8 encoded. This means that in the presence
% of non-ASCII characters, it will not work with BibTeX 0.99 or older.
% Instead, you should use an up-to-date BibTeX implementation like “bibtex8” or
% “biber”.
@ARTICLE{Singh:10735,
author = {Singh, R. and Lee, P.D. and Lindley, T.C. and Hellmich, C
and Bram, M. and Imwinkelried, T. and Dashwood, R.J.},
title = {{C}haracterization of the deformation behavior of
intermediate porosity interconnected {T}i foams using
micro-computed tomography and direct finite element
modelling},
journal = {Acta biotechnologica},
volume = {6},
issn = {0138-4988},
address = {Berlin},
publisher = {Wiley VCH},
reportid = {PreJuSER-10735},
pages = {2342 - 2351},
year = {2010},
note = {The authors acknowledge the useful discussions and
assistance of R.C. Atwood and R. Hamilton with the mu CT
studies. Andreas Fritsch (Technische Universitat Wien) is
gratefully acknowledged for his assistance with the
continuum micromechanics modeling. We thank the European
Synchrotron Radiation Facility for the provision of
synchrotron radiation facilities and especially the team of
beam line ID19. We would also like to thank the EPSRC
(GR/T26344) for support for the computational facilities and
one of the authors (R.S.) gratefully acknowledges financial
support from the EC under a Marie Curie Fellowship Grant.},
abstract = {Under load-bearing conditions metal-based foam scaffolds
are currently the preferred choice as bone/cartilage
implants. In this study X-ray micro-computed tomography was
used to discretize the three-dimensional structure of a
commercial titanium foam used in spinal fusion devices.
Direct finite element modeling, continuum micromechanics and
analytical models of the foam were employed to characterize
the elasto-plastic deformation behavior. These results were
validated against experimental measurements, including
ultrasound and monotonic and interrupted compression
testing. Interrupted compression tests demonstrated
localized collapse of pores unfavorably oriented with
respect to the loading direction at many isolated locations,
unlike the Ashby model, in which pores collapse row by row.
A principal component analysis technique was developed to
quantify the pore anisotropy which was then related to the
yield stress anisotropy, indicating which isolated pores
will collapse first. The Gibson-Ashby model was extended to
incorporate this anisotropy by considering an orthorhombic,
rather than a tetragonal, unit cell. It is worth noting that
the natural bone is highly anisotropic and there is a need
to develop and characterize anisotropic implants that mimic
bone characteristics.},
keywords = {Biocompatible Materials: chemistry / Computer Simulation /
Elastic Modulus / Finite Element Analysis / Gases: chemistry
/ Hardness / Materials Testing / Models, Chemical / Stress,
Mechanical / Titanium: chemistry / Tomography, X-Ray
Computed: methods / Biocompatible Materials (NLM Chemicals)
/ Gases (NLM Chemicals) / Titanium (NLM Chemicals) / J
(WoSType)},
cin = {IEF-1},
ddc = {570},
cid = {I:(DE-Juel1)VDB809},
pnm = {Rationelle Energieumwandlung},
pid = {G:(DE-Juel1)FUEK402},
shelfmark = {Engineering, Biomedical / Materials Science, Biomaterials},
typ = {PUB:(DE-HGF)16},
pubmed = {pmid:19961958},
UT = {WOS:000278250100055},
doi = {10.1016/j.actbio.2009.11.032},
url = {https://juser.fz-juelich.de/record/10735},
}
guest ::