TY - JOUR
T1 - Precision of digital volume correlation approaches for strain analysis in bone imaged with micro-computed tomography at different dimensional levels
AU - Dall'Ara, Enrico
AU - Peña Fernández, Marta
AU - Palanca, Marco
AU - Giorgi, Mario
AU - Cristofolini, Luca
AU - Tozzi, Gianluca
N1 - Funding Information:
The project was partially funded by the FP7 European program (MAMBO: PIEF-GA-2012-327357), the Engineering and Physical Sciences Research Council (Frontier Grant Multisim, EP/K03877X/1), the National Royal Society (RG130831 and RG150012), and the UK National Centre for the Replacement, Refinement and Reduction of Animals in Research (NC3Rs, grant number: NC/K000780/1). MP acknowledges the “Marco Polo” travel grant awarded by University of Bologna. The authors would like to thank the Diamond Light Source for time at the Diamond-Manchester Imaging Beamline I13-2 (under proposals: MT10315-Dall’Ara and MT14080-Tozzi), the SkeletAl (University of Sheffield), and the Zeiss Global Center (University of Portsmouth) for imaging and post-processing. We further acknowledge Prof. Hose and Prof. Barber for sharing the ShIRT scripts, Dr. Hollis (LaVision Ltd.) for assistance with DaVis software, Dr. Bodey for help with the acquisition of the Synchrotron images, and Dr. Danesi, Ms. Innocente, Mr. Morellato, and Dr. Boudiffa for help in the preparation and scanning of the samples. The whole or partial datasets used in this study can be found at the following figshare links: vertebral bodies scanned with μCT (https://doi.org/10.6084/m9.figshare.4062351.v1); vertebral bodies with bone cement scanned with μCT (https://doi. org/10.6084/m9.figshare.4308926.v2); cortical bone, trabecular bone, and mouse proximal tibia scanner with SRμCT (https:// doi.org/10.15131/shef.data.4865300.v1); trabecular bone with and without biomaterial scanned with SRμCT (https://figshare. com/s/9e30505b66d77276cc9a); and mouse tibiae scanned with in vivo and ex vivo μCT (https://doi.org/10.15131/shef. data.5528104).
Funding Information:
The project was partially funded by the FP7 European program (MAMBO: PIEF-GA-2012-327357), the Engineering and Physical Sciences Research Council (Frontier Grant Multisim, EP/K03877X/1), the National Royal Society (RG130831 and RG150012), and the UK National Centre for the Replacement, Refinement and Reduction of Animals in Research (NC3Rs, grant number: NC/K000780/1). MP acknowledges the “Marco Polo” travel grant awarded by University of Bologna. The authors would like to thank the Diamond Light Source for time at the Diamond-Manchester Imaging Beamline I13-2 (under proposals: MT10315-Dall’Ara and MT14080-Tozzi), the SkeletAl (University of Sheffield), and the Zeiss Global Center (University of Portsmouth) for imaging and post-processing. We further acknowledge Prof. Hose and Prof. Barber for sharing the ShIRT scripts, Dr. Hollis (LaVision Ltd.) for assistance with DaVis software, Dr. Bodey for help with the acquisition of the Synchrotron images, and Dr. Danesi, Ms. Innocente, Mr. Morellato, and Dr. Boudiffa for help in the preparation and scanning of the samples. The whole or partial datasets used in this study can be found at the following figshare links: vertebral bodies scanned with μCT (https://doi.org/10.6084/m9.figshare.4062351.v1); vertebral bodies with bone cement scanned with μCT (https://doi.org/10.6084/m9.figshare.4308926.v2); cortical bone, trabecular bone, and mouse proximal tibia scanner with SRμCT (https://doi.org/10.15131/shef.data.4865300.v1); trabecular bone with and without biomaterial scanned with SRμCT (https://figshare.com/s/9e30505b66d77276cc9a); and mouse tibiae scanned with in vivo and ex vivo μCT (https://doi.org/10.15131/shef.data.5528104).
Publisher Copyright:
© 2017 Dall’Ara, Peña-Fernández, Palanca, Giorgi, Cristofolini and Tozzi.
PY - 2017/11/8
Y1 - 2017/11/8
N2 - Accurate measurement of local strain in heterogeneous and anisotropic bone tissue is fundamental to understand the pathophysiology of musculoskeletal diseases, to evaluate the effect of interventions from preclinical studies, and to optimize the design and delivery of biomaterials. Digital volume correlation (DVC) can be used to measure the three-dimensional displacement and strain fields from micro-computed tomography (μCT) images of loaded specimens. However, this approach is affected by the quality of the input images, by the morphology and density of the tissue under investigation, by the correlation scheme, and by the operational parameters used in the computation. Therefore, for each application, the precision of the method should be evaluated. In this paper, we present the results collected from datasets analyzed in previous studies as well as new data from a recent experimental campaign for characterizing the relationship between the precision of two different DVC approaches and the spatial resolution of the outputs. Different bone structures scanned with laboratory source μCT or synchrotron light μCT (SRμCT) were processed in zero-strain tests to evaluate the precision of the DVC methods as a function of the subvolume size that ranged from 8 to 2,500 µm. The results confirmed that for every microstructure the precision of DVC improves for larger subvolume size, following power laws. However, for the first time, large differences in the precision of both local and global DVC approaches have been highlighted when SRμCT or in vivo μCT images were used instead of conventional ex vivo μCT. These findings suggest that in situ mechanical testing protocols applied in SRμCT facilities should be optimized to allow DVC analyses of localized strain measurements. Moreover, for in vivo μCT applications, DVC analyses should be performed only with relatively course spatial resolution for achieving a reasonable precision of the method. In conclusion, we have extensively shown that the precision of both tested DVC approaches is affected by different bone structures, different input image resolution, and different subvolume sizes. Before each specific application, DVC users should always apply a similar approach to find the best compromise between precision and spatial resolution of the measurements.
AB - Accurate measurement of local strain in heterogeneous and anisotropic bone tissue is fundamental to understand the pathophysiology of musculoskeletal diseases, to evaluate the effect of interventions from preclinical studies, and to optimize the design and delivery of biomaterials. Digital volume correlation (DVC) can be used to measure the three-dimensional displacement and strain fields from micro-computed tomography (μCT) images of loaded specimens. However, this approach is affected by the quality of the input images, by the morphology and density of the tissue under investigation, by the correlation scheme, and by the operational parameters used in the computation. Therefore, for each application, the precision of the method should be evaluated. In this paper, we present the results collected from datasets analyzed in previous studies as well as new data from a recent experimental campaign for characterizing the relationship between the precision of two different DVC approaches and the spatial resolution of the outputs. Different bone structures scanned with laboratory source μCT or synchrotron light μCT (SRμCT) were processed in zero-strain tests to evaluate the precision of the DVC methods as a function of the subvolume size that ranged from 8 to 2,500 µm. The results confirmed that for every microstructure the precision of DVC improves for larger subvolume size, following power laws. However, for the first time, large differences in the precision of both local and global DVC approaches have been highlighted when SRμCT or in vivo μCT images were used instead of conventional ex vivo μCT. These findings suggest that in situ mechanical testing protocols applied in SRμCT facilities should be optimized to allow DVC analyses of localized strain measurements. Moreover, for in vivo μCT applications, DVC analyses should be performed only with relatively course spatial resolution for achieving a reasonable precision of the method. In conclusion, we have extensively shown that the precision of both tested DVC approaches is affected by different bone structures, different input image resolution, and different subvolume sizes. Before each specific application, DVC users should always apply a similar approach to find the best compromise between precision and spatial resolution of the measurements.
KW - Bone
KW - Deformable registration
KW - Digital volume correlation
KW - Micro-computed tomography
KW - Precision
KW - Strain
UR - http://www.scopus.com/inward/record.url?scp=85052232551&partnerID=8YFLogxK
U2 - 10.3389/fmats.2017.00031
DO - 10.3389/fmats.2017.00031
M3 - Article
AN - SCOPUS:85052232551
SN - 2296-8016
VL - 4
JO - Frontiers in Materials
JF - Frontiers in Materials
M1 - 31
ER -