On the modeling of human intervertebral disc annulus fibrosus: Elastic, permanent deformation and failure responses

As a primary load-resisting component, annulus fibrosus (AF) maintains structural integrity of the entire intervertebral disc. Experiments have demonstrated that permanent deformation and damage take place in the tissue under mechanical loads. Development of an accurate model to capture the complex...

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Bibliographic Details
Published in:Journal of biomechanics 2020-03, Vol.102, p.109463-109463, Article 109463
Main Authors: Ghezelbash, Farshid, Shirazi-Adl, Aboulfazl, Baghani, Mostafa, Eskandari, Amir Hossein
Format: Article
Language:English
Subjects:
Annuli
Annulus fibrosus
Annulus Fibrosus - anatomy & histology
Annulus Fibrosus - physiology
Axial loads
Axial stress
Biomechanical Phenomena
Calibration
Collagen
Composite materials
Compression
Constitutive models
Damage
Deformation
Displacement
Elastic deformation
Elasticity
Energy
Fiber orientation
Finite element
Humans
Intervertebral discs
Load
Mathematical models
Model testing
Models, Biological
Performance evaluation
Poisson's ratio
Preconditioning
Pressure
Stress, Mechanical
Stress-strain curves
Structural integrity
Unloading
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Summary:As a primary load-resisting component, annulus fibrosus (AF) maintains structural integrity of the entire intervertebral disc. Experiments have demonstrated that permanent deformation and damage take place in the tissue under mechanical loads. Development of an accurate model to capture the complex behaviour of AF tissue is hence crucial in disc model studies. We, therefore, aimed to develop a non-homogenous model to capture elastic, inelastic and failure responses of the AF tissue and the entire disc model under axial load. Our model estimations satisfactorily agreed with results of existing uniaxial (along fiber, circumferential and axial directions) and biaxial tissue-level tests. The model accurately predicted the failure of the tissue in various directions in uniaxial extension. Collagen fiber content, type and orientation substantially altered AF tissue responses in uni- and bi-axial tests. Although collagen fiber content and type mostly affected failure stress, fiber orientation significantly influenced the tissue failure strain. The entire L2-L3 disc model accurately replicated load–displacement as well as loading-unloading responses of the disc under compression-tension forces. Preconditioning of the disc-body unit substantially stiffened response. Poisson’s ratio of both AF and nucleus considerably affected compression-displacement responses of the disc (173% increase in compression at 1.49 mm displacement when it was changed from 0.499 to 0.49999). Any AF constitutive model should be calibrated under various tissue-level loads and directions as well as the entire disc model responses since using a single tissue-level loading (e.g. uniaxial) for calibration can lead to unrealistic responses in other tests (e.g., biaxial). Special attentions should be given to the choice of Poisson’s ratio and the realistic consideration of preconditioning load.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2019.109463