Abstract

Automobile crashes and blunt traumaoften lead to life-threatening thoracic injuries, especially to the lung tissues. These injuries can be simulated using finite element-based human bodymodels that need dynamic material properties of lung tissue. The strain-rate-dependent material parameters of human parenchymal tissues were determined in this study using uniaxial quasi-static (1mm/s) and dynamic (1.6, 3, and 5m/s) compression tests. A bilinear material model was used to capture the nonlinear behavior of the lung tissue, which was implemented using a user-defined material in LS-DYNA. Inverse mapping using genetic algorithm-based optimization of all experimental data with the corresponding FE models yielded a set of strain-rate-dependent material parameters. The bilinear material parameters are obtained for the strain rates of 0.1, 100, 300, and 500s-1. The estimated elastic modulus increased from 43 to 153kPa, while the toe strain reduced from 0.39 to 0.29 when the strain rate was increased from 0.1 to 500s-1. The optimized bilinear material properties of parenchymal tissue exhibit a piecewise linear relationship with the strain rate.

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