TY - GEN
T1 - Constructing a multi-scan synchrotron X-ray microscope to study the function of osteocyte canaliculi in mouse bone
AU - Nango, Nobuhito
AU - Kubota, Shogo
AU - Yashiro, Wataru
AU - Momose, Atsushi
AU - Takada, Yasunari
AU - Matsuo, Koichi
PY - 2012
Y1 - 2012
N2 - Formulating a multi-scan method applied to an X-ray microscope CT with synchrotron radiation, we attempted to analyze the 3D functional structure of osteocyte canaliculi inside the cortical bone of a mouse tibia. We employed a two-method combination to scan the same position of the specimen. To extract the internal bone canalicular structure, we first combined a Talbot interferometer with an X-ray microscope, and applied a differential phase imaging method to measure the absolute value of bone mineral around the canaliculi. Next, we used the X-ray microscope without the Talbot interferometer under a defocus condition, moving the specimen toward the zone plate by 6 mm. This defocus contrast method visualizes the canaliculi by emphasizing the edges of the bone. We performed CT scans by the two configurations and precisely aligned resultant 3D images so that the same position in the specimen is compared. We could extract the osteocyte canaliculi and evaluate the mineral density of their surroundings. The degree of mineralization varied for each osteocyte lacuna and canaliculus. The multi-scan microscopic X-ray CT is a powerful tool for analyzing bone mineralization.
AB - Formulating a multi-scan method applied to an X-ray microscope CT with synchrotron radiation, we attempted to analyze the 3D functional structure of osteocyte canaliculi inside the cortical bone of a mouse tibia. We employed a two-method combination to scan the same position of the specimen. To extract the internal bone canalicular structure, we first combined a Talbot interferometer with an X-ray microscope, and applied a differential phase imaging method to measure the absolute value of bone mineral around the canaliculi. Next, we used the X-ray microscope without the Talbot interferometer under a defocus condition, moving the specimen toward the zone plate by 6 mm. This defocus contrast method visualizes the canaliculi by emphasizing the edges of the bone. We performed CT scans by the two configurations and precisely aligned resultant 3D images so that the same position in the specimen is compared. We could extract the osteocyte canaliculi and evaluate the mineral density of their surroundings. The degree of mineralization varied for each osteocyte lacuna and canaliculus. The multi-scan microscopic X-ray CT is a powerful tool for analyzing bone mineralization.
KW - Phase contrast
KW - Synchrotron Radiation
KW - Talbot interferometry
KW - X-ray microscope
UR - http://www.scopus.com/inward/record.url?scp=84873262681&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84873262681&partnerID=8YFLogxK
U2 - 10.1063/1.4742292
DO - 10.1063/1.4742292
M3 - Conference contribution
AN - SCOPUS:84873262681
SN - 9780735410725
T3 - AIP Conference Proceedings
SP - 199
EP - 204
BT - International Workshop on X-Ray and Neutron Phase Imaging with Gratings
T2 - International Workshop on X-Ray and Neutron Phase Imaging with Gratings, XNPIG 2012
Y2 - 5 March 2012 through 7 March 2012
ER -