Lower cervical spine motion segment computational model validation: kinematic and kinetic response for quasi-static and dynamic loading

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Barker, Jeffrey B.¹; Cronin, Duane S.^1,2; Nightingale, Roger W.³

Lower cervical spine motion segment computational model validation: kinematic and kinetic response for quasi-static and dynamic loading

J Biomech Eng. June 2017;139(6):061009

©2017 ASME

Affiliations

¹Department of Mechatronics and Mechanical Engineering, University of Waterloo, 200 University Avenue West, Waterloo, ON N2L 3G1, Canada

²Department of Mechanical Engineering, University of Waterloo, 200 University Avenue West, Waterloo, ON N2L 3G1, Canada

³Division of Orthopaedic Surgery, Department of Biomedical Engineering, Duke University, Box 90281, Durham, NC 27708-0281
Abstract

Advanced computational human body models (HBM) enabling enhanced safety require verification and validation at different levels or scales. Specifically, the motion segments, which are the building blocks of a detailed neck model, must be validated with representative experimental data to have confidence in segment and, ultimately, full neck model response. In this study, we introduce detailed finite element motion segment models and assess the models for quasi-static and dynamic loading scenarios. Finite element segment models at all levels in the lower human cervical spine were developed from scans of a 26-yr old male subject. Material properties were derived from the in vitro experimental data. The segment models were simulated in quasi-static loading in flexion, extension, lateral bending and axial rotation, and at dynamic rates in flexion and extension in comparison to previous experimental studies and new dynamic experimental data introduced in this study. Single-valued experimental data did not provide adequate information to assess the model biofidelity, while application of traditional corridor methods highlighted that data sets with higher variability could lead to an incorrect conclusion of improved model biofidelity. Data sets with continuous or multiple moment–rotation measurements enabled the use of cross-correlation for an objective assessment of the model and highlighted the importance of assessing all motion segments of the lower cervical spine to evaluate the model biofidelity. The presented new segment models of the lower cervical spine, assessed for range of motion and dynamic/traumatic loading scenarios, provide a foundation to construct a biofidelic model of the spine and neck, which can be used to understand and mitigate injury for improved human safety in the future.
Links

DOI: 10.1115/1.4036464

PubMed: 28418508

WoS: 000400901600009
History

Received: 2016-10-31

Revised: 2017-03-17

Online: 2017-05-02

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2020	Fabre MAC. Development of Elderly Posture Male and Female Finite Element Neck Models and Assessment of Tissue-Level Response Under Impact Loading [Master's thesis]. University of Waterloo; 2020.
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2022	Darweesh M. Evaluating Cervical Spine Response and Potential for Injury During Head-First Impact Loading Using a Finite Element Head-Neck Model [Master's thesis]. University of Waterloo; 2022.
2022	Rycman AL. Computational Modeling of the Cervical Spinal Cord: Integration Into a Human Body Model to Investigate Response to Impact [PhD thesis]. University of Waterloo; 2022.
2023	Carroll GA. Experimental Characterization and Finite Element Modelling of Cervical Facet Joint Mechanics [Master's thesis]. University of Waterloo; 2023.
2019	Bian K. Predicting and Preventing Traumatic Brain Injury: A Novel Computational Approach [Master's thesis]. London, ON: Western University; August 2019.
2023	Bian K. Understanding Real-World and Laboratory Traumatic Brain Injury (TBI) Using the Computational Model With Brain Functional Regions [PhD thesis]. University of Western Ontario; 2023.