Barry S. Myers scite author profile

Blast-related traumatic brain injury is the most prevalent injury for combat personnel seen in the current conflicts in Iraq and Afghanistan, yet as a research community,we still do not fully understand the detailed etiology and pathology of this injury. Finite element (FE) modeling is well suited for studying the mechanical response of the head and brain to blast loading. This paper details the development of a FE head and brain model for blast simulation by examining both the dilatational and deviatoric response of the brain as potential injury mechanisms. The levels of blast exposure simulated ranged from 50 to 1000 kPa peak incident overpressure and 1–8 ms in positive-phase duration, and were comparable to real-world blast events. The frontal portion of the brain had the highest pressures corresponding to the location of initial impact, and peak pressure attenuated by 40–60% as the wave propagated from the frontal to the occipital lobe. Predicted brain pressures were primarily dependent on the peak overpressure of the impinging blast wave, and the highest predicted brain pressures were 30%less than the reflected pressure at the surface of blast impact. Predicted shear strain was highest at the interface between the brain and the CSF. Strain magnitude was largely dependent on the impulse of the blast, and primarily caused by the radial coupling between the brain and deforming skull.The largest predicted strains were generally less than 10%,and occurred after the shock wave passed through the head.For blasts with high impulses, CSF cavitation had a large role in increasing strain levels in the cerebral cortex and periventricular tissues by decoupling the brain from the skull. Relating the results of this study with recent experimental blast testing suggest that a rate-dependent strain-based tissue injury mechanism is the source primary blast TBI.

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The Cervical Facet Capsule and Its Role in Whiplash Injury

Winkelstein¹,

Nightingale²,

Richardson³

et al. 2000

Spine

186

142

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

Nightingale

McElhaney

Richardson

et al. 1996

Journal of Biomechanics

161

119

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The role of strength in rising from a chair in the functionally impaired elderly

Hughes

Myers

Schenkman

1996

Journal of Biomechanics

254

110

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Comparative strengths and structural properties of the upper and lower cervical spine in flexion and extension

Nightingale

Winkelstein

Knaub

et al. 2002

Journal of Biomechanics

120

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Quantifying Skeletal Muscle Properties in Cadaveric Test Specimens: Effects of Mechanical Loading, Postmortem Time, and Freezer Storage

Chasse

Myers

1999

128

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Investigators currently lack the data necessary to define the state of skeletal muscle properties within cadaveric specimens. The purpose of this study is to define the temporal changes in the postmortem properties of skeletal muscle as a function of mechanical loading and freezer storage. The tibialis anterior of the New Zealand white rabbit was chosen for study. Modulus and no-load strain were found to vary significantly from live after eight hours postmortem. Following the changes that occur during rigor mortis, a stable region of postmortem, post-rigor properties occurred between 36 to 72 hours postmortem. A freeze-thaw process was not found to have a significant effect on the post-rigor response. The first loading cycle response of post-rigor muscle was unrepeatable but stiffer than live passive muscle. After preconditioning, the post-rigor muscle response was repeatable. The preconditioned post-rigor response was less stiff than the live passive response due to a significant increase in no-load strain. Failure properties of postmortem muscle were found to be significantly different from live passive muscle with a significant decrease in failure stress (61 percent) and energy (81 percent), while failure strain was unchanged. These results suggest that the post-rigor response of cadaveric muscle is unaffected by freezing but sensitive to even a few cycles of mechanical loading.

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Rapid neck muscle adaptation alters the head kinematics of aware and unaware subjects undergoing multiple whiplash-like perturbations

Siegmund

Sanderson

Myers

et al. 2003

Journal of Biomechanics

109

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Awareness Affects the Response of Human Subjects Exposed to a Single Whiplash-Like Perturbation

Siegmund¹,

Sanderson²,

Myers³

et al. 2003

Spine

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Barry S. Myers

Development of a Finite Element Model for Blast Brain Injury and the Effects of CSF Cavitation

The Cervical Facet Capsule and Its Role in Whiplash Injury

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

The role of strength in rising from a chair in the functionally impaired elderly

Comparative strengths and structural properties of the upper and lower cervical spine in flexion and extension

Quantifying Skeletal Muscle Properties in Cadaveric Test Specimens: Effects of Mechanical Loading, Postmortem Time, and Freezer Storage

Rapid neck muscle adaptation alters the head kinematics of aware and unaware subjects undergoing multiple whiplash-like perturbations

Awareness Affects the Response of Human Subjects Exposed to a Single Whiplash-Like Perturbation

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