Journal article
A. Alshareef, J. S. Giudice, J. Forman, D. Shedd, K. Reynier, Taotao Wu
2019
2019
Semantic Scholar
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APA
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Alshareef, A., Giudice, J. S., Forman, J., Shedd, D., Reynier, K., & Wu, T. (2019). I. INTRODUCTION Finite element models of the human brain are the state-of-the-art technique for simulating real-world head impacts to assess brain injury risk, investigate potential neurotrauma mechanisms, and develop injury.
Chicago/Turabian
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Alshareef, A., J. S. Giudice, J. Forman, D. Shedd, K. Reynier, and Taotao Wu. “I. INTRODUCTION Finite Element Models of the Human Brain Are the State-of-the-Art Technique for Simulating Real-World Head Impacts to Assess Brain Injury Risk, Investigate Potential Neurotrauma Mechanisms, and Develop Injury” (2019).
MLA
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Alshareef, A., et al. I. INTRODUCTION Finite Element Models of the Human Brain Are the State-of-the-Art Technique for Simulating Real-World Head Impacts to Assess Brain Injury Risk, Investigate Potential Neurotrauma Mechanisms, and Develop Injury. 2019.
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@article{a2019a,
title = {I. INTRODUCTION Finite element models of the human brain are the state-of-the-art technique for simulating real-world head impacts to assess brain injury risk, investigate potential neurotrauma mechanisms, and develop injury},
year = {2019},
author = {Alshareef, A. and Giudice, J. S. and Forman, J. and Shedd, D. and Reynier, K. and Wu, Taotao}
}
Abstract
Finite element models of the human brain are the state-of-the-art technique for simulating real-world head impacts to assess brain injury risk, investigate potential neurotrauma mechanisms, and develop injury countermeasures. However, these models must be validated to human brain deformation. Recently, a technique was developed using sonomicrometry to record 3D brain motion data in a human cadaver model subjected to injurious conditions generated using a controlled dynamic rotation of the head [1]. Leveraging this technique, the objective of this study was to generate a dataset of dynamic brain deformation collected from multiple specimens under various kinematic conditions to investigate the relationship between brain deformation magnitude and the characteristics of the applied head loading.
