TY - JOUR
T1 - Non-destructive three-dimensional evaluation of a polymer sponge by micro-tomography using synchrotron radiation
AU - Müller, Bert
AU - Beckmann, Felix
AU - Huser, Marius
AU - Maspero, Fabrice
AU - Székely, Gábor
AU - Ruffieux, Kurt
AU - Thurner, Philipp
AU - Wintermantel, Erich
PY - 2002/8
Y1 - 2002/8
N2 - X-ray micro-tomography, a non-destructive technique is used to uncover the complex 3-D micro-architecture of a degradable polymer sponge designed for bone augmentation. The measurements performed at HASYLAB at DESY are based on a synchrotron radiation source resulting in a spatial resolution of about 5.4 μm. In the present communication we report the quantitative analysis of the porosity and of the pore architecture. First, we elucidate that synchrotron radiation at the photon energy of 9 keV has an appropriate cross section for this low-weight material. Modifications in sponge micro-architecture during measurement are not detected. Second, the treatment of the data, an amount of 2.5 Gbyte to generate binary data is described. We compare the 3-D with the 2-D analysis in a quantitative manner. The obtained values for the mean distance to material within the sponge calculated from 2-D and 3-D data of the whole tomogram differ significantly: 12.5 μm for 3-D and 17.6 μm for 2-D analysis. If the pores exhibit a spherical shape as frequently found, the derived mean pore diameter, however, is overestimated only by 6% in the 2-D image analysis with respect to the 3-D evaluation. This approach can be applied to different porous biomaterials and composites even in a hydrated state close to physiological conditions, where any surface preparation artifact is avoided.
AB - X-ray micro-tomography, a non-destructive technique is used to uncover the complex 3-D micro-architecture of a degradable polymer sponge designed for bone augmentation. The measurements performed at HASYLAB at DESY are based on a synchrotron radiation source resulting in a spatial resolution of about 5.4 μm. In the present communication we report the quantitative analysis of the porosity and of the pore architecture. First, we elucidate that synchrotron radiation at the photon energy of 9 keV has an appropriate cross section for this low-weight material. Modifications in sponge micro-architecture during measurement are not detected. Second, the treatment of the data, an amount of 2.5 Gbyte to generate binary data is described. We compare the 3-D with the 2-D analysis in a quantitative manner. The obtained values for the mean distance to material within the sponge calculated from 2-D and 3-D data of the whole tomogram differ significantly: 12.5 μm for 3-D and 17.6 μm for 2-D analysis. If the pores exhibit a spherical shape as frequently found, the derived mean pore diameter, however, is overestimated only by 6% in the 2-D image analysis with respect to the 3-D evaluation. This approach can be applied to different porous biomaterials and composites even in a hydrated state close to physiological conditions, where any surface preparation artifact is avoided.
KW - Biodegradable scaffold
KW - Porosity
KW - Synchrotron radiation
KW - Three-dimensional image analysis
KW - X-ray microtomography
UR - http://www.scopus.com/inward/record.url?scp=0036668133&partnerID=8YFLogxK
U2 - 10.1016/S1389-0344(02)00014-X
DO - 10.1016/S1389-0344(02)00014-X
M3 - Article
C2 - 12202165
AN - SCOPUS:0036668133
SN - 1389-0344
VL - 19
SP - 73
EP - 78
JO - Biomolecular Engineering
JF - Biomolecular Engineering
IS - 2-6
ER -