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Study on Cervical Spine Stresses Based on Three-Dimensional Finite Element Method

To establish three dimensional finite element model of the whole cervical spine and investigate biomechanical characteristic of the human cervical spine for application of clinical diagnosis and therapy. Method: A healthy adult female was subjected, three dimensional finite element model of the whol...

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Main Authors:	Zhang Lian-jie, Meng Qing-jun
Format:	Conference Proceeding
Language:	English
Subjects:	Biological system modeling Biomechanics Cervical Spine Data models Finite element method Finite element methods Load modeling Solid modeling Spine Stress
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creator	Zhang Lian-jie Meng Qing-jun
description	To establish three dimensional finite element model of the whole cervical spine and investigate biomechanical characteristic of the human cervical spine for application of clinical diagnosis and therapy. Method: A healthy adult female was subjected, three dimensional finite element model of the whole cervical spine was established using the method of 3D interpolation with CT. Result: The model included seven vertebrae, five discs, postical structure and seven ligaments. The volume of the whole model is 74 878.34mm 3 , the surface area is 32 616.04mm 2 , which consisting of 578 007 elements, 123 358 nodes, comparing the simulation data with the literature, the validity of the model was verified. Conclusion: The three-dimensional finite element model simulates the structure and property of cervical spine, whose structure is whole, its elements is fine, the model is very accurate and credible. The equivalent (Von Mises) stress of centum, facet joints and intervertebral disc in flexion is higher than in extension, the result of the biomechanical study was better correlated with the available experimental data. This indicates that the model can be used to analyze the biomechanics characteristic of the human cervical spine f in different condition.
doi_str_mv	10.1109/ICCIS.2010.109
format	conference_proceeding
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Method: A healthy adult female was subjected, three dimensional finite element model of the whole cervical spine was established using the method of 3D interpolation with CT. Result: The model included seven vertebrae, five discs, postical structure and seven ligaments. The volume of the whole model is 74 878.34mm 3 , the surface area is 32 616.04mm 2 , which consisting of 578 007 elements, 123 358 nodes, comparing the simulation data with the literature, the validity of the model was verified. Conclusion: The three-dimensional finite element model simulates the structure and property of cervical spine, whose structure is whole, its elements is fine, the model is very accurate and credible. The equivalent (Von Mises) stress of centum, facet joints and intervertebral disc in flexion is higher than in extension, the result of the biomechanical study was better correlated with the available experimental data. 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Method: A healthy adult female was subjected, three dimensional finite element model of the whole cervical spine was established using the method of 3D interpolation with CT. Result: The model included seven vertebrae, five discs, postical structure and seven ligaments. The volume of the whole model is 74 878.34mm 3 , the surface area is 32 616.04mm 2 , which consisting of 578 007 elements, 123 358 nodes, comparing the simulation data with the literature, the validity of the model was verified. Conclusion: The three-dimensional finite element model simulates the structure and property of cervical spine, whose structure is whole, its elements is fine, the model is very accurate and credible. The equivalent (Von Mises) stress of centum, facet joints and intervertebral disc in flexion is higher than in extension, the result of the biomechanical study was better correlated with the available experimental data. This indicates that the model can be used to analyze the biomechanics characteristic of the human cervical spine f in different condition.</abstract><pub>IEEE</pub><doi>10.1109/ICCIS.2010.109</doi><tpages>4</tpages></addata></record>
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Biological system modeling Biomechanics Cervical Spine Data models Finite element method Finite element methods Load modeling Solid modeling Spine Stress
title	Study on Cervical Spine Stresses Based on Three-Dimensional Finite Element Method
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