Separating brain motion into rigid body displacement and deformation under low-severity impacts

Zou, Hong; Schmiedeler, James P.; Hardy, Warren N.

Affiliations

¹Department of Mechanical Engineering, The Ohio State University, 650 Ackerman Road, Suite 255, Columbus, OH 43202, USA

²Department of Mechanical Engineering, The Ohio State University, 228 Building 1, 650 Ackerman Road, Columbus, OH 43202, USA

³Department of Biomedical Engineering, Wayne State University Bioengineering Center, 818 West Hancock, Rm 2131, Detroit, MI 48201, USA

Abstract and keywords

The relative motion of the brain with respect to the skull has been widely studied to investigate brain injury mechanisms under impacts, but the motion patterns are not yet thoroughly understood. This work analyzes brain motion patterns using the most recent and advanced experimental relative brain/skull motion data collected under low-severity impacts. With a minimum total pseudo-strain energy, the closed-form solutions for rigid body translation and rotation were obtained by matching measured neutral density target (NDT) positions with initial NDT positions. The brain motion was thus separated into rigid body displacement and deformation. The results show that the brain has nearly pure rigid body displacement at low impact speed. As the impact becomes more severe, the increased brain motion primarily is due to deformation, while the rigid body displacement is limited in magnitude for both translation and rotation. Under low-severity impacts in the sagittal plane, the rigid body brain translation has a magnitude of 4–5 mm, and the whole brain rotation is on the order of ±5°.

Keywords: Brain injury; Biomechanics; Strain energy; Rigid body displacement; Deformation

Links

DOI: 10.1016/j.jbiomech.2006.06.018

PubMed: 16919640

WoS: 000246004500001

History

Revised: 2006-06-13

Accepted: 2006-06-13

Online: 2006-08-21

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Cited By (15)

Year	Entry
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2018	Taylor K. The Use of Decoupling Structures in Helmet Liners to Reduce Maximum Principal Brain Tissue Strain for Head Impacts [PhD thesis]. University of Ottawa; 2018.
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2010	Lockhart PA. Primary Blast Injury of the Head: Numerical Prediction and Evaluation of Protection [Master's thesis]. University of Waterloo; 2010.
2017	Guettler AJ. Quantifying the Response of Relative Brain/skull Motion to Rotational Input in the PMHS Head [Master's thesis]. Virginia Polytechnic Institute and State University; December 18, 2017.
2007	Hardy WN. Response of the Human Cadaver Head to Impact [PhD thesis]. Detroit, MI: Wayne State University; December 2007.