Cervical spine posture, but not head-end motion constraints, governs the kinematic and kinetic response in sub-injurious axial impacts
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(Published version)
Date
2026
Authors
Thompson-Bagshaw, D.W.
Quarrington, R.D.
Cripton, P.A.
Jones, C.F.
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Journal article
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Journal of the Mechanical Behavior of Biomedical Materials, 2026; 175:107321-1-107321-10
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Darcy W. Thompson-Bagshaw, Ryan D. Quarrington, Peter A. Cripton, Claire F. Jones
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Abstract
Head-first impacts can produce traumatic cervical spine injuries resulting in tetraplegia. These injury patterns are thought to relate to the alignment of the loading vector relative to the spinal column. Pre-impact posture and subsequent head and intervertebral kinematics, including spinal buckling and head motion relative to the spine and torso, can generate complex spinal configurations. These motions often precede injury onset and can be observed with ex vivo models in which applied loads remain below injury thresholds. This study examined the kinematic response of the cervical spine to dynamic axial compression at sub-injurious severities, enabling interand intra-specimen comparisons across varying initial spinal postures and head motion constraints. Human cervical spine specimens (N = 7) were subjected to repeated 1 m/s axial impacts, while the applied head constraint (sagittal rotation and/or anterior translation) and initial posture (anterior eccentricity and curvature) were varied. Pre-impact head–T1 eccentricity and curvature, head-end motion during impact, intervertebral kinematics, and impact loads were recorded. Head-end anterior translation and flexion rotation were minimal across all constraint conditions (<11.5 mm, <9.0°). Head constraint had no detected effect on peak force (541–2457 N), deformation (3.2–11 mm), or stiffness (81–1074 N/mm) (all p > 0.05). In contrast, greater initial curvature and eccentricity reduced stiffness and peak force, and increased deformation (p < 0.05). Greater initial curvature also produced larger changes in intervertebral flexion-extension during impact (p < 0.05). These results demonstrate that pre-impact posture dictates the cervical spine’s sub-injurious axial response at discrete anterior eccentricities, which may be further explored using computational models validated using this dataset.
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Available online 22 December 2025
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© 2025 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).