Finite element analysis of the spine: towards a framework of verification, validation and sensitivity analysis

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Jones, Alison C.¹; Wilcox, Ruth K.¹

Finite element analysis of the spine: towards a framework of verification, validation and sensitivity analysis

Med Eng Phys. December 2008;30(10):1287-1304

©2008 Published by Elsevier Ltd on behalf of IPEM

Affiliations

¹School of Mechanical Engineering, University of Leeds, Leeds LS2 9JT, UK
Abstract and keywords

A number of papers have recently emphasised the importance of verification, validation and sensitivity testing in computational studies within the field of biomechanical engineering. This review examines the methods used in the development of spinal finite element models with a view to a standardised framework of verification, validation and sensitivity analysis. The scope of this paper is restricted to models of the vertebra, the intervertebral disc and short spinal segments. In the case of single vertebral models, specimen-specific methods have been developed, which allow direct validation against experimental tests. The focus of intervertebral disc modelling has been on representing the complex material properties and further sensitivity testing is required to fully understand the relative roles of these input parameters. In order to construct complex multi-component short segment models, many geometric and material parameters are required, some of which are yet to be fully characterised. There are also major challenges in terms of short segment model validation. Throughout the review, areas of good practise are highlighted and recommendations for future development are proposed, taking a step towards more robust spinal modelling procedures, promoting acceptance from the wider biomechanics community.

Keywords: Finite element analysis; Computational models; Spine; Vertebra; Intervertebral disc
Links

DOI: 10.1016/j.medengphy.2008.09.006

PubMed: 18986824

WoS: 000261914400008
History

Received: 2008-04-11

Revised: 2008-09-24

Accepted: 2008-09-25

Cited Works (23)

Year	Entry
2001	Homminga J, Huiskes R, Van Rietbergen B, Rüegsegger P, Weinans H. Introduction and evaluation of a gray-value voxel conversion technique. J Biomech. April 2001;34(4):513-517.
1997	Maurel N, Lavaste F, Skalli W. A three-dimensional parameterized finite element model of the lower cervical spine, study of the influence of the posterior articular facets. J Biomech. September 1997;30(9):921-931.
2003	Crawford RP, Rosenberg WS, Keaveny TM. Quantitative computed tomography-based finite element models of the human lumbar vertebral body: effect of element size on stiffness, damage, and fracture strength predictions. J Biomech Eng. August 2003;125(4):434-438.
2003	Liebschner MAK, Kopperdahl DL, Rosenberg WS, Keaveny TM. Finite element modeling of the human thoracolumbar spine. Spine. March 15, 2003;28(6):559-565.
1984	Shirazi-Adl SA, Shrivastava SC, Ahmed A. Stress analysis of the lumbar disc-body unit in compression: a three-dimensional nonlinear finite element study. Spine. March 1984;9(2):120-134.
2002	Kopperdahl DL, Morgan EF, Keaveny TM. Quantitative computed tomography estimates of the mechanical properties of human vertebral trabecular bone. J Orthop Res. July 2002;20(4):801-805.
1991	Faulkner KG, Cann CE, Hasegawa BH. Effect of bone distribution on vertebral strength: assessment with patient-specific nonlinear finite element analysis. Radiology. June 1991;179(3):669-674.
2004	Brolin K, Halldin P. Development of a finite element model of the upper cervical spine and a parameter study of ligament characteristics. Spine. February 15, 2004;29(4):376-385.
2005	Yeni YN, Christopherson GT, Dong XN, Kim D-G, Fyhrie DP. Effect of microcomputed tomography voxel size on the finite element model accuracy for human cancellous bone. J Biomech Eng. February 2005;127(1):1-8.
2001	Homminga J, Weinans H, Gowin W, Felsenberg D, Huiskes R. Ostehoporosis changes the amount of vertebral trabecular bone at risk of fracture but not the vertebral load distribution. Spine. July 2001;26(14):1555-1560.
2007	Eswaran SK, Gupta A, Keaveny TM. Locations of bone tissue at high risk of initial failure during compressive loading of the human vertebral body. Bone. October 2007;41(4):733-739.
2001	Teo EC, Ng HW. Evaluation of the role of ligaments, facets and disc nucleus in lower cervical spine under compression and sagittal moments using finite element method. Med Eng Phys. April 2001;23(3):155-164.
2007	Schileo E, Taddei F, Malandrino A, Cristofolini L, Viceconti M. Subject-specific finite element models can accurately predict strain levels in long bones. J Biomech. 2007;40(13):2982-2989.
1985	Simon BR, Wu JSS, Carlton MW, Evans JH, Kazarian LE. Structural models for human spinal motion segments based on a poroelastic view of the intervertebral disk. J Biomech Eng. November 1985;107(4):327-335.
2003	Baer AE, Laursen TA, Guilak F, Setton LA. The micromechanical environment of intervertebral disc cells determined by a finite deformation, anisotropic, and biphasic finite element model. J Biomech Eng. February 2003;125(1):1-11.
1992	Lavaste F, Skalli W, Robin S, Roy-Camille R, Mazel C. Three-dimensional geometrical and mechanical modelling of the lumbar spine. J Biomech. October 1992;25(10):1153-1164.
1996	Argoubi M, Shirazi-Adl A. Poroelastic creep response analysis of a lumbar motion segment in compression. J Biomech. October 1996;29(10):1331-1339.
2007	Buckley JM, Loo K, Motherway J. Comparison of quantitative computed tomography-based measures in predicting vertebral compressive strength. Bone. March 2007;40(3):767-774.
1993	Mosekilde L. Vertebral structure and strength in vivo and in vitro. Calcif Tiss Int. February 1993;53(suppl 1):S121-S126.
2003	Crawford RP, Cann CE, Keaveny TM. Finite element models predict in vitro vertebral body compressive strength better than quantitative computed tomography. Bone. 2003;33(4):744-750.
1999	Kumaresan S, Yoganandan N, Pintar FA, Maiman DJ. Finite element modeling of the cervical spine: role of intervertebral disc under axial and eccentric loads. Med Eng Phys. December 1999;21(10):689-700.
2003	Whyne CM, Hu SS, Lotz JC. Burst fracture in the metastatically involved spine: development, validation, and parametric analysis of a three-dimensional poroelastic finite-element model. Spine. April 1, 2003;28(7):652-660.
2004	Ferguson SJ, Ito K, Nolte L-P. Fluid flow and convective transport of solutes within the intervertebral disc. J Biomech. February 2004;37(2):213-221.

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2012	Jones AC, Wijayathunga VN, Rehman S, Wilcox RK. Subject-specific models of the spine for the analysis of vertebroplasty. In: Gefen A, ed. Patient-Specific Modelling in Tomorrow's Medicine. Berlin: Springer-Verlag; 2012:133-154. Studies in Mechanobiology, Tissue Engineering and Biomaterials; vol 9.
2020	Butz KD, Spurlock CM, Lister K. Validation of the CAVEMAN human body model lumbar spine response to vertical accelerative loading and the effect of spine curvature on skeletal fracture. In: Proceedings of the 2020 International IRCOBI Conference on the Biomechanics of Injury. 2020; Munich, Germany.113-122.
2017	Dall’Ara E, Peña-Fernández M, Palanca M, Giorgi M, Cristofolini L, Tozzi G. Precision of digital volume correlation approaches for strain analysis in bone imaged with micro-computed tomography at different dimensional levels. Front Mater. November 8, 2017;4:31.
2016	Palanca M, Tozzi G, Cristofolini L. The use of digital image correlation in the biomechanical area: a review. Int Biomech. 2016;3(1):1-21.
2010	Halloran JP, Ackermann M, Erdemir A, van den Bogert AJ. Concurrent musculoskeletal dynamics and finite element analysis predicts altered gait patterns to reduce foot tissue loading. J Biomech. 2010;43(14):2810-2815.
2013	Burkhart TA, Andrews DM, Dunning CE. Finite element modeling mesh quality, energy balance and validation methods: a review with recommendations associated with the modeling of bone tissue. J Biomech. May 31, 2013;46(9):1477-1488.
2016	Jackman TM, DelMonaco AM, Morgan EF. Accuracy of finite element analyses of CT scans in predictions of vertebral failure patterns under axial compression and anterior flexion. J Biomech. January 25, 2016;49(2):267-275.
2011	Unnikrishnan GU, Morgan EF. A new material mapping procedure for quantitative computed tomography-based, continuum finite element analyses of the vertebra. J Biomech Eng. July 2011;133(7):071001.
2015	Jackman TM. Prediction of Vertebral Fractures Under Axial Compression and Anterior Flexion [PhD thesis]. Boston University; 2015.
2016	Cisewski SE. Nutrient Related Mechanisms of Intervertebral Disc Degeneration [PhD thesis]. Clemson, SC: Clemson University; August 2016.
2012	Smith SD. Computationally Efficient Finite Element Models of the Lumbar Spine for the Evaluation of Spine Mechanics and Device Performance [Master's thesis]. University of Denver; March 2012.
2017	Christou A. Modelling Spinal Injury Due to High-Rate Axial Loading [PhD thesis]. Imperial College London; June 2017.
2016	Frazer LL. Stresses Associated With Subchondral Bone Cysts: A Finite Element Analysis on an Extended Stifle Joint [Master's thesis]. Lawrence, KS: University of Kansas; 2016.
2022	El Bojairami I. Assessment of Static Spinal Stability and Muscle Activation Strategies: A Comprehensive Approach Via a Novel Validated Finite Elements Spine Model Inclusive of Thoracolumbar Fascia, Intramuscular Pressure, and Intra-Abdominal Pressure [PhD thesis]. McGill University; April 2022.
2018	Gluek C. Evaluating the Mechanical Response of Novel Synthetic Femurs Representing Osteoporotic Bone [Master's thesis]. Hamilton, ON: McMaster University; August 2018.
2014	Yoder A. Low Back Biomechanics During Walking of Individuals With a Lower-Limb Amputation [Master's thesis]. Colorado School of Mines; 2014.
2015	Campbell JQ. Population-Based Methods to Evaluate the Effect of Anatomical Variation on Lumbar Spine Biomechanics [PhD thesis]. Colorado School of Mines; 2015.
2014	Anderst W. In Vivo Cervical Spine Kinematics, Arthrokinematics and Disc Loading in Asymptomatic Control Subjects and Anterior Fusion Patients [PhD thesis]. University of Pittsburgh; 2014.
2011	Driscoll M. Design, Optimization, and Evaluation of a Fusionless Device to Induce Growth Modulation and Correct Spinal Curvatures in Adolescent Idiopathic Scoliosis [PhD thesis]. École polytechnique de Montréal; June 2011.
2011	Wagnac É. Expérimentation et modélisation détaillée de la colonne vertébrale pour étudier le rôle de facteurs anatomiques et biomécaniques sur les traumatismes rachidiens [PhD thesis]. École polytechnique de Montréal; November 2011.
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2019	Rastegar Talzali S. Biomechanical Modeling of Transforaminal Lumbar Interbody Fusion: A Comparative Assessment of Segmental Lumbar Lordosis and Risk of Cage Subsidence With Different Cage Heights and Placements [Master's thesis]. École polytechnique de Montréal; May 2019.
2018	Groenen KHJ. Spinal (in)stability in Metastatic Bone Disease: Experimental, Computational, and Clinical Perspectives [PhD thesis]. Radboud University; 2018.
2012	Dall'Ara E. QCT Based Finite Element Models of the Human Vertebra and Femur: Validation With Experiments and Comparison With Bone Densitometry [PhD thesis]. Vienna University of Technology; October 2012.
2014	Gross T. Development and Application of 3d CT Image-Based Micro and Macro Finite Element Models for Human Bones and Orthopedic Implant Systems [PhD thesis]. Vienna University of Technology; 2014.
2016	Gustafson HM. Quantifying the Response of Vertebral Bodies to Compressive Loading Using Digital Image Correlation [PhD thesis]. Vancouver, BC: University of British Columbia; October 2016.
2020	Pai S A. Investigation of Thoracic Spine and Muscle Morphology With Open Upright MRI [Master's thesis]. Vancouver, BC: University of British Columbia; December 2020.
2013	Maquer G. Image-Based Biomechanical Assessment of Vertebral Body and Intervertebral Disc in the Human Lumbar Spine [PhD thesis]. Universität Bern; March 2013.
2017	Palanca M. In Vitro Full-Field Methods for the Biomechanical Characterization of Spine Segments [PhD thesis]. University of Bologna; March 2017.
2014	Tan K. Characterising the Viscoelasticity of Soft Biological Tissues Under Large Deformation [PhD thesis]. University of New South Wales; March 2014.
2012	Hojjat S-P. Automated Quantitative Analysis of Bone Stability and Tumour Burden in the Metastatic Rat Spine [PhD thesis]. University of Toronto; 2012.
2018	Khor F. Computational Modeling of Hard Tissue Response and Fracture in the Lower Cervical Spine Under Compression Including Age Effects [Master's thesis]. University of Waterloo; 2018.