Dynamic responses of the head and cervical spine to axial impact loading

This study explores the inertial effects of the head and torso on cervical spine dynamics with the specific goal of determining whether the head mass can provide a constraining cervical spine end condition. The hypothesis was tested using a low friction impact surface and a pocketing foam impact sur...

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Bibliographic Details
Published in:Journal of biomechanics 1996-03, Vol.29 (3), p.307-318
Main Authors: Nightingale, Roger W., McElhaney, James H., Richardson, William J., Myers, Barry S.
Format: Article
Language:English
Subjects:
Adult
Aged
Biomechanical Phenomena
Buckling
Cervical spine
Cervical Vertebrae - injuries
Cervical Vertebrae - physiology
Dynamics
Female
Fractures, Comminuted - etiology
Fractures, Comminuted - physiopathology
Friction
Head - physiology
Humans
Impact
Injury
Intervertebral Disc - injuries
Intervertebral Disc - physiopathology
Male
Middle Aged
Movement
Rotation
Rupture
Skull Fractures - etiology
Skull Fractures - physiopathology
Space life sciences
Spinal Fractures - etiology
Spinal Fractures - physiopathology
Spinal Injuries - etiology
Spinal Injuries - physiopathology
Stress, Mechanical
Surface Properties
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Summary:This study explores the inertial effects of the head and torso on cervical spine dynamics with the specific goal of determining whether the head mass can provide a constraining cervical spine end condition. The hypothesis was tested using a low friction impact surface and a pocketing foam impact surface. Impact orientation was also varied. Tests were conducted on whole unembalmed heads and cervical spines using a drop track system to produce impact velocities on the order of 3.2 ms −1. Data for the head impact forces and the reactions at T1 were recorded and the tests were also imaged at 1000 frames s −1. Injuries occurred 2–19 ms following head impact and prior to significant head motion. Average compressive load a failure was 1727 ± 387 N. Decoupling was observed between the head and T1. Cervical spine loading due to head rebound constituted up to 54 ± 16% of the total axial neck load for padded impacts and up to 38 ± 30% of the total axial neck load for rigid impacts. Dynamic buckling was also observed; including first-order modes and transient higher-order modes which shifted the structure from a primarily compressive mode of deformation to various bending modes. These experiments demonstrate that in the absence of head pocketing, the head mass can provide sufficient constraint to cause cervical spine injury. The results also show that cervical spinal injury dynamics are complex, and that a large sample size of experimentally produced injuries will be necessary to develop comprehensive neck injury models and criteria.
ISSN:0021-9290
1873-2380
DOI:10.1016/0021-9290(95)00056-9