Ultrastructural Properties in Cortical Bone Vary Greatly in Two Inbred Strains of Mice as Assessed by Synchrotron Light Based Micro‐ and Nano‐CT

Nondestructive SR‐based μCT and nano‐CT methods have been designed for 3D quantification and morphometric analysis of ultrastructural phenotypes within murine cortical bone, namely the canal network and the osteocyte lacunar system. Results in two different mouse strains, C57BL/6J‐Ghrhrlit/J and C3....

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Published in:Journal of bone and mineral research 2007-10, Vol.22 (10), p.1557-1570
Main Authors: Schneider, Philipp, Stauber, Martin, Voide, Romain, Stampanoni, Marco, Donahue, Leah Rae, Müller, Ralph
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
biomechanics
Bone and Bones - ultrastructure
bone ultrastructure
canal network
Female
Fundamental and applied biological sciences. Psychology
Imaging, Three-Dimensional
Light
Male
Mice
Nanostructures - ultrastructure
nano‐CT
negative imaging
Osteoclasts - cytology
osteocyte lacunae
Skeleton and joints
Stress, Mechanical
synchrotron radiation
Synchrotrons
Tomography Scanners, X-Ray Computed
Vertebrates: osteoarticular system, musculoskeletal system
μCT
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Summary:Nondestructive SR‐based μCT and nano‐CT methods have been designed for 3D quantification and morphometric analysis of ultrastructural phenotypes within murine cortical bone, namely the canal network and the osteocyte lacunar system. Results in two different mouse strains, C57BL/6J‐Ghrhrlit/J and C3.B6‐Ghrhrlit/J, showed that the cannular and lacunar morphometry and their bone mechanics were fundamentally different. Introduction: To describe the different aspects of bone quality, we followed a hierarchical approach and assessed bone tissue properties in different regimens of spatial resolution, beginning at the organ level and going down to cellular dimensions. For these purposes, we developed different synchrotron radiation (SR)‐based CT methods to assess ultrastructural phenotypes of murine bone. Materials and Methods: The femoral mid‐diaphyses of 12 C57BL/6J‐Ghrhrlit/J (B6‐lit/lit) and 12 homozygous mutants C3.B6‐Ghrhrlit/J (C3.B6‐lit/lit) were measured with global SR μCT and local SR nano‐CT (nCT) at nominal resolutions ranging from 3.5 μm to 700 nm, respectively. For volumetric quantification, morphometric indices were determined for the cortical bone, the canal network, and the osteocyte lacunar system using negative imaging. Moreover, the biomechanics of B6‐lit/lit and C3.B6‐lit/lit mice was determined by three‐point bending. Results: The femoral mid‐diaphysis of C3.B6‐lit/lit was larger compared with B6‐lit/lit mice. On an ultrastructural level, the cannular indices for C3.B6‐lit/lit were generally bigger in comparison with B6‐lit/lit mice. Accordingly, we derived and showed a scaling rule, saying that overall cannular indices scaled with bone size, whereas indices describing basic elements of cannular and lacunar morphometry did not. Although in C3.B6‐lit/lit, the mean canal volume was larger than in B6‐lit/lit, canal number density was proportionally smaller in C3.B6‐lit/lit, so that lacuna volume density was found to be constant and therefore independent of mouse strain and sex. The mechanical properties in C3.B6‐lit/lit were generally improved compared with B6‐lit/lit specimens. For C3.B6‐lit/lit, we observed a sex specificity of the mechanical parameters, which could not be explained by bone morphometry on an organ level. However, there is evidence that for C3.B6‐lit/lit, the larger cortical bone mass is counterbalanced or even outweighed by the larger canal network in the female mice. Conclusions: We established a strategy to subdivide murine
ISSN:0884-0431
1523-4681
DOI:10.1359/jbmr.070703