Image-based multiscale mechanical modeling shows the importance of structural heterogeneity in the human lumbar facet capsular ligament

The lumbar facet capsular ligament (FCL) primarily consists of aligned type I collagen fibers that are mainly oriented across the joint. The aim of this study was to characterize and incorporate in-plane local fiber structure into a multiscale finite element model to predict the mechanical response...

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Bibliographic Details
Published in:Biomechanics and modeling in mechanobiology 2017-08, Vol.16 (4), p.1425-1438
Main Authors: Zarei, Vahhab, Liu, Chao J., Claeson, Amy A., Akkin, Taner, Barocas, Victor H.
Format: Article
Language:English
Subjects:
Alignment
Biological and Medical Physics
Biomechanical Phenomena
Biomechanics
Biomedical Engineering and Bioengineering
Biophysics
Cadaver
Cadavers
Collagen Type I
Engineering
Fiber orientation
Fibers
Finite element analysis
Finite element method
Heterogeneity
Humans
In vitro methods and tests
Ligaments
Ligaments, Articular - physiology
Mathematical models
Mechanical analysis
Mechanical tests
Medical imaging
Models, Biological
Neurons
Optical Coherence Tomography
Original Paper
Polarization
Strain
Strain distribution
Stress concentration
Stress, Mechanical
Strip
Structural models
Theoretical and Applied Mechanics
Tomography, Optical Coherence
Zygapophyseal Joint - physiology
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Summary:The lumbar facet capsular ligament (FCL) primarily consists of aligned type I collagen fibers that are mainly oriented across the joint. The aim of this study was to characterize and incorporate in-plane local fiber structure into a multiscale finite element model to predict the mechanical response of the FCL during in vitro mechanical tests, accounting for the heterogeneity in different scales. Characterization was accomplished by using entire-domain polarization-sensitive optical coherence tomography to measure the fiber structure of cadaveric lumbar FCLs ( n = 6 ). Our imaging results showed that fibers in the lumbar FCL have a highly heterogeneous distribution and are neither isotropic nor completely aligned. The averaged fiber orientation was + 9 . 3 ∘ ( + 29 . 9 ∘ in the inferior region and + 5 . 1 ∘ in the middle and superior regions), with respect to lateral–medial direction (superior–medial to inferior–lateral). These imaging data were used to construct heterogeneous structural models, which were then used to predict experimental gross force–strain behavior and the strain distribution during equibiaxial and strip biaxial tests. For equibiaxial loading, the structural model fit the experimental data well but underestimated the lateral–medial forces by ∼ 16% on average. We also observed pronounced heterogeneity in the strain field, with stretch ratios for different elements along the lateral–medial axis of sample typically ranging from about 0.95 to 1.25 during a 12% strip biaxial stretch in the lateral–medial direction. This work highlights the multiscale structural and mechanical heterogeneity of the lumbar FCL, which is significant both in terms of injury prediction and microstructural constituents’ (e.g., neurons) behavior.
ISSN:1617-7959
1617-7940
DOI:10.1007/s10237-017-0896-4