Journal ArticleDOI
Finite element lumbar spine facet contact parameter predictions are affected by the cartilage thickness distribution and initial joint gap size
Daniel J. Woldtvedt,Wesley J. Womack,Benjamin C. Gadomski,Dieter Schuldt,Christian M. Puttlitz +4 more
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TLDR
The data indicate that range of motion predictions alone are insufficient to establish model validation intended to predict mechanical contact parameters, and emphasize the need for the careful consideration of the initial facet joint gap thickness with respect to the spinal condition being studied.Abstract:
Current finite element modeling techniques utilize geometrically inaccurate cartilage distribution representations in the lumbar spine. We hypothesize that this shortcoming severely limits the predictive fidelity of these simulations. Specifically, it is unclear how these anatomically inaccurate cartilage representations alter range of motion and facet contact predictions. In the current study, cadaveric vertebrae were serially sectioned, and images were taken of each slice in order to identify the osteochondral interface and the articulating surface. A series of custom-written algorithms were utilized in order to quantify each facet joint's three-dimensional cartilage distribution using a previously developed methodology. These vertebrae-dependent thickness cartilage distributions were implemented on an L1 through L5 lumbar spine finite element model. Moments were applied in three principal planes of motion, and range of motion and facet contact predictions from the variable thickness and constant thickness distribution models were determined. Initial facet gap thickness dimensions were also parameterized. The data indicate that the mean and maximum cartilage thickness increased inferiorly from L1 to L5, with an overall mean thickness value of 0.57 mm. Cartilage distribution and initial facet joint gap thickness had little influence on the lumbar range of motion in any direction, whereas the mean contact pressure, total contact force, and total contact area predictions were altered considerably. The data indicate that range of motion predictions alone are insufficient to establish model validation intended to predict mechanical contact parameters. These data also emphasize the need for the careful consideration of the initial facet joint gap thickness with respect to the spinal condition being studied.read more
Citations
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Journal ArticleDOI
Comparison of eight published static finite element models of the intact lumbar spine: Predictive power of models improves when combined together
Marcel Dreischarf,Thomas Zander,Aboulfazl Shirazi-Adl,Christian M. Puttlitz,Clayton J. Adam,C.S. Chen,Vijay K. Goel,Ata M. Kiapour,Yoon Hyuk Kim,Kevin M. Labus,J.P. Little,Won Man Park,Y.H. Wang,Hans-Joachim Wilke,Antonius Rohlmann,Hendrik Schmidt,Hendrik Schmidt +16 more
TL;DR: In this article, the pooled median of individual model results, similar to a probabilistic approach, can be used as an improved predictive tool in order to estimate the response of the lumbar spine.
Journal ArticleDOI
Biomechanical response of lumbar facet joints under follower preload: a finite element study.
TL;DR: An analysis combining patterns of contact pressure distribution, facet load, contact area and contact pressure can provide more insight into the biomechanical role of facets under various moment loadings and follower loads.
Journal ArticleDOI
In vivo loads in the lumbar L3-4 disc during a weight lifting extension.
TL;DR: This study provided quantitative data on in vivo disc loading that could help understand intrinsic biomechanics of the spine and improve surgical treatment of pathological discs using fusion or arthroplasty techniques.
Journal ArticleDOI
Automated finite element modeling of the lumbar spine: Using a statistical shape model to generate a virtual population of models
TL;DR: Functional finite element models of the mean shape and the extreme shapes of all 17 shape modes were created demonstrating the robust nature of the methods and will allow population-based modeling in the future.
Journal ArticleDOI
FEBio finite element models of the human lumbar spine.
TL;DR: This modeling framework currently targets three deficient areas in the field of lumbar spine modeling: open-access models, accessibility for multiple meshing schemes, and options to include advanced hyperelastic and biphasic constitutive models.
References
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Book
Clinical Anatomy of the Lumbar Spine and Sacrum
TL;DR: The Lumbar Vertebrae are described as well as the Sacrum, the Sacro-Iliac Joint, the Intervertebral Discs, and the Zygapophysial Joints, which are connected to the Tournaisian Spine.
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TL;DR: This study provides a comprehensive study on the role of facets and ligaments and their geometry in preserving segmental stability and predicts that facet osteoerthritis or hypertrophy leading to spinal stenosis is most likely under flexion-anterior shear loading, and selective facetectomy may restore spinal canal size without compromising the stability of the segment.
Journal ArticleDOI
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TL;DR: In this article, the three-dimensional coordinates of various marked points on the surface of the vertebra were measured with a specially designed morphometer instrument, from these coordinates, linear dimensions, angulations, and areas of surfaces and cross-sections of most vertebral components were calculated.