Quantitative computed tomography-based finite-element analysis (QCT/FEA) has become increasingly popular in an attempt to understand and possibly reduce vertebral fracture risk. It is known that scanning acquisition settings affect Hounsfield units (HU) of the CT voxels. Material properties assignments in QCT/FEA, relating HU to Young's modulus, are performed by applying empirical equations. The purpose of this study was to evaluate the effect of QCT scanning protocols on predicted stiffness values from finite-element models. One fresh frozen cadaveric torso and a QCT calibration phantom were scanned six times varying voltage and current and reconstructed to obtain a total of 12 sets of images. Five vertebrae from the torso were experimentally tested to obtain stiffness values. QCT/FEA models of the five vertebrae were developed for the 12 image data resulting in a total of 60 models. Predicted stiffness was compared to the experimental values. The highest percent difference in stiffness was approximately 480% (80 kVp, 110 mAs, U70), while the lowest outcome was ∼1% (80 kVp, 110 mAs, U30). There was a clear distinction between reconstruction kernels in predicted outcomes, whereas voltage did not present a clear influence on results. The potential of QCT/FEA as an improvement to conventional fracture risk prediction tools is well established. However, it is important to establish research protocols that can lead to results that can be translated to the clinical setting.
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September 2016
Research-Article
Quantitative Computed Tomography Protocols Affect Material Mapping and Quantitative Computed Tomography-Based Finite-Element Analysis Predicted Stiffness
Hugo Giambini,
Hugo Giambini
Biomaterials and Tissue Engineering Laboratory,
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: giambini.hugo@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: giambini.hugo@mayo.edu
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Dan Dragomir-Daescu,
Dan Dragomir-Daescu
Division of Engineering,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: dragomirdaescu.dan@mayo.edu
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: dragomirdaescu.dan@mayo.edu
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Ahmad Nassr,
Ahmad Nassr
Division of Orthopedic Research,
Department of Orthopedic Surgery,
Mayo Clinic,
Rochester, MN 55905
e-mail: nassr.ahmad@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic,
Rochester, MN 55905
e-mail: nassr.ahmad@mayo.edu
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Michael J. Yaszemski,
Michael J. Yaszemski
Biomaterials and Tissue Engineering Laboratory,
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: yaszemski.michael@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: yaszemski.michael@mayo.edu
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Chunfeng Zhao
Chunfeng Zhao
Biomechanics Laboratory,
Division of Orthopedic Research,
Mayo Clinic,
Rochester, MN 55905
e-mail: zhao.chunfeng@mayo.edu
Division of Orthopedic Research,
Mayo Clinic,
Rochester, MN 55905
e-mail: zhao.chunfeng@mayo.edu
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Hugo Giambini
Biomaterials and Tissue Engineering Laboratory,
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: giambini.hugo@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: giambini.hugo@mayo.edu
Dan Dragomir-Daescu
Division of Engineering,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: dragomirdaescu.dan@mayo.edu
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: dragomirdaescu.dan@mayo.edu
Ahmad Nassr
Division of Orthopedic Research,
Department of Orthopedic Surgery,
Mayo Clinic,
Rochester, MN 55905
e-mail: nassr.ahmad@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic,
Rochester, MN 55905
e-mail: nassr.ahmad@mayo.edu
Michael J. Yaszemski
Biomaterials and Tissue Engineering Laboratory,
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: yaszemski.michael@mayo.edu
Department of Orthopedic Surgery,
Mayo Clinic College of Medicine,
Rochester, MN 55905
e-mail: yaszemski.michael@mayo.edu
Chunfeng Zhao
Biomechanics Laboratory,
Division of Orthopedic Research,
Mayo Clinic,
Rochester, MN 55905
e-mail: zhao.chunfeng@mayo.edu
Division of Orthopedic Research,
Mayo Clinic,
Rochester, MN 55905
e-mail: zhao.chunfeng@mayo.edu
1Corresponding author.
Manuscript received February 23, 2016; final manuscript received July 6, 2016; published online July 29, 2016. Assoc. Editor: Joel D. Stitzel.
J Biomech Eng. Sep 2016, 138(9): 091003 (7 pages)
Published Online: July 29, 2016
Article history
Received:
February 23, 2016
Revised:
July 6, 2016
Citation
Giambini, H., Dragomir-Daescu, D., Nassr, A., Yaszemski, M. J., and Zhao, C. (July 29, 2016). "Quantitative Computed Tomography Protocols Affect Material Mapping and Quantitative Computed Tomography-Based Finite-Element Analysis Predicted Stiffness." ASME. J Biomech Eng. September 2016; 138(9): 091003. https://doi.org/10.1115/1.4034172
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