Ústav technické a experimentální fyziky Institute of Experimental and Applied Physics

Displacement Tracking in Single Human Trabecula with Metal-plated Micro-spheres using X-ray Radiography Imaging

NázevTitle
Displacement Tracking in Single Human Trabecula with Metal-plated Micro-spheres using X-ray Radiography ImagingDisplacement Tracking in Single Human Trabecula with Metal-plated Micro-spheres using X-ray Radiography Imaging
Druh výsledkuResult type
Článek v časopiseJournal article
AutořiAuthors
O. Jiroušek, D. Kytýř, T. Doktor, J. Dammer, F. Krejčí
DOIDOI
10.1088/1748-0221/8/02/C02041
Časopis / citaceJournal / citation
Journal of Instrumentation. 2013, 8(2), ISSN 1748-0221.
RokYear
2013
JazykLanguage
eng
WoSWoS
000315672700041
ScopusScopus
2-s2.0-84875542995
RIVRIV
RIV/68407700:21670/13:00202165!RIV14-MSM-21670___
ProjektProject
Využití radionuklidů a ionizujícího zářeníApplication of radionuclides and ionising radiation

AbstraktAbstract

This study presents an improved radiographic method for strain measurement in very small samples of a single trabeculae. X-ray micro-radiography was used to track the deformation behaviour of individual trabecula during mechanical loading. As the X-ray micro-radiography images of a single trabecula show no significant features applicable for digital image correlation (DIC) a random pattern of markers was created on the surfaces of the samples to improve the accuracy of tracking. Metal plated borosilicate glassmicro-spheres (mean diameter 10um) were used as the markers for trabecular displacement tracking. Two different X-ray imaging setups were used for this purpose. The specimens of isolated trabeculae were loaded by amicro-mechanical testing device developed with respect to radiographical observation. This compact device enables a high precision three-point bending measurement. The specimen was continuously irradiated during the loading procedure by amicro-focus X-ray source. The radiographs were acquired by a single-photon counting silicon pixel detector and s flat panel sensor with CsI flipped scintillator plate. Circular Hough transform was used to locate positions of the spherical markers in the sequence of acquired radiographs and to calculate the strain in the loaded sample. The gold-coated micro-spheres provide clearly visible features in the sequence of radiographs after beam hardening correction, which in conjunction with pattern recognition algorithm enables to substantially improve the accuracy of strain measurements.

This study presents an improved radiographic method for strain measurement in very small samples of a single trabeculae. X-ray micro-radiography was used to track the deformation behaviour of individual trabecula during mechanical loading. As the X-ray micro-radiography images of a single trabecula show no significant features applicable for digital image correlation (DIC) a random pattern of markers was created on the surfaces of the samples to improve the accuracy of tracking. Metal plated borosilicate glassmicro-spheres (mean diameter 10um) were used as the markers for trabecular displacement tracking. Two different X-ray imaging setups were used for this purpose. The specimens of isolated trabeculae were loaded by amicro-mechanical testing device developed with respect to radiographical observation. This compact device enables a high precision three-point bending measurement. The specimen was continuously irradiated during the loading procedure by amicro-focus X-ray source. The radiographs were acquired by a single-photon counting silicon pixel detector and s flat panel sensor with CsI flipped scintillator plate. Circular Hough transform was used to locate positions of the spherical markers in the sequence of acquired radiographs and to calculate the strain in the loaded sample. The gold-coated micro-spheres provide clearly visible features in the sequence of radiographs after beam hardening correction, which in conjunction with pattern recognition algorithm enables to substantially improve the accuracy of strain measurements.