Modular Use of Human Body Models of Various Complexities in the Head and Thoraco-Abdominal Regions

The field of injury biomechanics is constantly evolving, and with it, the tools available for researchers. Computational modeling is one of these tools, specifically finite element human body models (HBMs). Finite element human body models can be used to investigate the mechanism and injury tolerance of various regions of the human body during blunt impact trauma through the use of computer simulation. These models can be used as a supplement to traditional crash test dummies for crash safety evaluation due to their affordability, ease of use, and increased available data points. As part of the Global Human Body Models Consortium (GHBMC) project, HBMs have developed and become more complex and biofidelic. They have also become more computationally expensive which may restrict usage from individuals with limited computational power. This motivated the development of faster running simplified HBMs similar to the detailed models, but restricted to analysis of kinematics and kinetics. In order to use the benefits from both types of models, we have developed an approach to modularly incorporate detailed components into the simplified models which allows the ability to obtain organ level response much faster than the full detailed model. The method has been implemented with the brain and thoracoabdominal cavity with comparable results to the detailed model, but with a time savings up to 90%. This thesis describes the implementation and evaluation of this modular method within the GHBMC 50th percentile male model.

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Year

Entry

2012

Shin J, Yue N, Untaroiu CD. A finite element model of the foot and ankle for automotive impact applications. Ann Biomed Eng. December 2012;40(12):2519-2531.

1987

Lau IV, Horsch JD, Viano DC, Andrzejak DV. Biomechanics of liver injury by steering wheel loading. J Trauma. March 1987;27(3):225-235.

2012

Vavalle NA. Validation of the Global Human Body Models Consortium Mid-Sized Male Model in Lateral Impacts and Sled Tests [Master's thesis]. Winston-Salem, NC: Wake Forest University; August 2012.

2003

Siegmund GP, Sanderson DJ, Myers BS, Inglis JT. Rapid neck muscle adaptation alters the head kinematics of aware and unaware subjects undergoing multiple whiplash-like perturbations. J Biomech. April 2003;36(4):473-482.

2015

Davis ML, Vavalle NA, Gayzik FS. An evaluation of mass-normalization using 50th and 95th percentile human body finite element models in frontal crash. In: Proceedings of the 2015 International IRCOBI Conference on the Biomechanics of Injury. September 9-11, 2015; Lyon, France.608-621.