Lumbar Spine Response of Computational Finite Element Models in Multidirectional Spaceflight Landing Conditions

Lumbar Spine Response of Computational Finite Element Models in Multidirectional Spaceflight Landing Conditions

The goals of this study are to compare the lumbar spine response variance between the hybrid III, test device for human occupant restraint (THOR), and global human body models consortium simplified 50th percentile (GHBMC M50-OS) finite element models and evaluate the sensitivity of lumbar spine inju...

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Bibliographic Details
Published in:Journal of biomechanical engineering Vol. 142; no. 5
Main Authors: Ye, Xin, Jones, Derek A, Gaewsky, James P, Koya, Bharath, McNamara, Kyle P, Saffarzadeh, Mona, Putnam, Jacob B, Somers, Jeffrey T, Gayzik, F Scott, Stitzel, Joel D, Weaver, Ashley A
Format: Journal Article
Language:English
Published: United States 01-05-2020
Subjects:
Biomechanical Phenomena
Computer Simulation
Finite Element Analysis
Humans
Lumbar Vertebrae - physiology
Mechanical Phenomena
Models, Biological
Space Flight
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Summary:The goals of this study are to compare the lumbar spine response variance between the hybrid III, test device for human occupant restraint (THOR), and global human body models consortium simplified 50th percentile (GHBMC M50-OS) finite element models and evaluate the sensitivity of lumbar spine injury metrics to multidirectional acceleration pulses for spaceflight landing conditions. The hybrid III, THOR, and GHBMC models were positioned in a baseline posture within a generic seat with side guards and a five-point restraint system. Thirteen boundary conditions, which were categorized as loading condition variables and environmental variables, were included in the parametric study using a Latin hypercube design of experiments. Each of the three models underwent 455 simulations for a total of 1365 simulations. The hybrid III and THOR models exhibited similar lumbar compression forces. The average lumbar compression force was 45% higher for hybrid III (2.2 ± 1.5 kN) and 51% higher for THOR (2.0 ± 1.6 kN) compared to GHBMC (1.3 ± 0.9 kN). Compared to hybrid III, THOR sustained an average 64% higher lumbar flexion moment and an average 436% higher lumbar extension moment. The GHBMC model sustained much lower bending moments compared to hybrid III and THOR. Regressions revealed that lumbar spine responses were more sensitive to loading condition variables than environmental variables across all models. This study quantified the intermodel lumbar spine response variations and sensitivity between hybrid III, THOR, and GHBMC. Results improve the understanding of lumbar spine response in spaceflight landings.
ISSN:1528-8951
DOI:10.1115/1.4045401