2012
DOI: 10.1016/j.jbiomech.2012.03.015
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Biomechanical characterisation of ovine spinal facet joint cartilage

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Cited by 13 publications
(12 citation statements)
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References 39 publications
(45 reference statements)
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“…These properties have been derived previously from experimental indentation tests using a computational model and iteratively altering the value of the cartilage properties until the predicted deformation–time curve matches that of the experimental test. 18 , 27 , 26 It is clear from the present study that such a deformation–time curve has a low sensitivity to the value of permeability. The maximum difference in the vertical displacement of the indenter was only 6.2%, compared to the initial curve, when the permeability decreased by 50%.…”
Section: Discussionmentioning
confidence: 64%
“…These properties have been derived previously from experimental indentation tests using a computational model and iteratively altering the value of the cartilage properties until the predicted deformation–time curve matches that of the experimental test. 18 , 27 , 26 It is clear from the present study that such a deformation–time curve has a low sensitivity to the value of permeability. The maximum difference in the vertical displacement of the indenter was only 6.2%, compared to the initial curve, when the permeability decreased by 50%.…”
Section: Discussionmentioning
confidence: 64%
“…In order to successfully engineer facet cartilage, it is critical that appropriate design criteria are established, which will ultimately provide the framework for the regeneration of a functional tissue replacement. Currently, there exist no experimental studies that characterize the biomechanical, biochemical, and histological properties of human cartilage, and only a few detailing the characteristics of animal facet cartilage [27,28]. With regard to the latter, the spines of quadrupeds receive different loading patterns when compared to bipeds, furthering the necessity for comparing the facet joints of humans and animals to develop suitable nonprimate animal models.…”
Section: Introductionmentioning
confidence: 99%
“…The SMZ is richly innervated and considered a source of pain (Buckland-Wright, 2004;Hayami et al, 2006;Intema et al, 2010) and computer models are often used to study the relationship between facet joint morphology and the mechanisms of lower back pain (Teo et al, 2004;Kuo et al, 2010). Improving both the anatomy and the mechanical properties in a model can enhance orthopedic treatment and surgery (Abd Latif et al, 2012;Niemeyer et al, 2012). For instance, the thickness of the SMZ is usually modeled as the thickness of the cortical shell [around 0.38 mm according to Eswaran et al (2005)], which is much thinner than this study suggests.…”
Section: Discussionmentioning
confidence: 99%
“…As osteoarthritis progresses, the load‐bearing role of the facet joints is altered (Adams and Hutton, ; Adams and Hutton, ; Yang and King, ); thus, facet joint sclerosis should affect SMZ thickness as much as SMZ tissue properties (i.e., BMD and porosity) and mechanical properties (i.e., modulus of elasticity). Whereas cartilage and trabecular bone have frequently been studied, few references concern the tissue and mechanical properties of facet joint SMZ (Jang and Kim, ; Abd Latif et al, ). Therefore, to provide reliable insights into the mechanism of osteoarthritic progression from CT scans, it is necessary to examine the morphology and biomechanical properties of the SMZ and their homogeneity within the facet joint.…”
Section: Introductionmentioning
confidence: 99%