Effect of displacement rate on the tensile mechanics of pediatric cervical functional spinal units

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Nuckley, David J.¹; Hertsted, Suzanne M.¹; Eck, Michael P.¹; Ching, Randal P.¹

Effect of displacement rate on the tensile mechanics of pediatric cervical functional spinal units

J Biomech. November 2005;38(11):2266-2275

©2004 Elsevier Ltd.All rights reserved.

Affiliations

¹Applied Biomechanics Laboratory, Department of Mechanical Engineering, University of Washington, 501 Eastlake Avenue East, Suite 102, Seattle, Washington, USA
Abstract and keywords

This study examined the effect of loading (displacement) rate on the tensile mechanics of cervical spine functional spinal units. A total of 40 isolated functional spinal units (two vertebrae and the adjoining soft tissues) from juvenile male baboons (10±0.6—human equivalent years old) were subjected to tensile loading spanning four orders of magnitude from 0.5 to 5000 mm/s. The stiffness, ultimate failure load, and corresponding displacement at failure were measured for each specimen and normalized by spinal geometry to examine the material properties as well as the structural properties. The tensile stiffness, failure load, normalized stiffness, and normalized failure load significantly increased (ANOVA, p<0.001) with increasing displacement rate. From the slowest to fastest loading rate, a two-fold increase in stiffness and four-fold increase in failure load were observed. The tensile failure strains (1.07±0.31 mm/mm strain) were not significantly correlated with loading rate (ANOVA, p=0.146). Both the functional (non-destructive stiffness and normalized stiffness) and failure mechanics of isolated functional spinal units exhibited a power-law relationship with displacement rate. Modeling efforts utilizing these rate-dependent characteristics will enhance our understanding of the tensile viscoelastic response of the spine and enable improved dynamic injury prevention schemes.

Keywords: Biomechanics; Loading rate; Cervical spine; Neck; Injury tolerance
Links

DOI: 10.1016/j.jbiomech.2004.09.021

PubMed: 16154414

WoS: 000232456400016
History

Accepted: 2004-09-06

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2013	Luck JF, Nightingale RW, Bass CRD. Compressive mechanical properties of the perinatal, neonatal and pediatric cervical spine. In: Proceedings of the 2013 International IRCOBI Conference on the Biomechanics of Injury. September 11-13, 2013; Gothenburg, Sweden.655-662.
2014	Arbogast KB. A public health priority for only ten percent of the car occupant population: why focus on children and how are they different biomechanically? In: Proceedings of the 2014 International IRCOBI Conference on the Biomechanics of Injury. September 10-12, 2014; Berlin, Germany.1-14.
2009	Arbogast KB, Balasubramanian S, Seacrist T, Maltese MR, García-España JF, Hopely T, Constans E, Lopez-Valdes FJ, Kent RW, Tanji H, Higuchi K. Comparison of kinematic responses of the head and spine for children and adults in low-speed frontal sled tests. Stapp Car Crash J. 2009;53:329-372. SAE 2009-22-0012.
2012	Arbogast KB, Mathews EA, Seacrist T, Maltese MR, Hammond R, Balasubramanian S, Kent RW, Tanji H, St. Lawrence S, Higuchi K. The effect of pretensioning and age on torso rollout in restrained human volunteers in far-side lateral and oblique loading. Stapp Car Crash J. October 2012;56:443-467.
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