Comparison of the Dynamic Response and Fracture Characteristics of Female and Male Lumbar Spine and Pelvis in Underbody Blast Loading

Underbody blast (UBB) attacks on US Military vehicles in the recent conflicts resulted in debilitating injuries to mounted Warfighters. Biomechanical research studies in the last decade aimed to understand UBB related injuries to guide protective technology designs for military ground vehicles. The design of protective seats is driven by injuries to the pelvis and lumbar spine, which are aligned with the vertical direction of UBB loading. When the US Military began to open many combat roles to female soldiers in 2016, a need arose to understand the impact of survivability and protection for the female Warfighter population as well. Although several exist for males, there are no published studies that explore female pelvis and lumbar spine response and injury in UBB loading. It is unknown whether skeletal differences between females and males in the pelvis and lumbar regions would result in different fracture thresholds and damage patterns. Thus, critical information is missing to inform the design of injury mitigating technologies that protect the full Warfighter population.

As part of a female pilot study, this research compared the effect of UBB loading on the pelvis and lumbar spine of females and males. Whole-body and component postmortem human surrogate (PMHS) tests were conducted to measure kinematic and injury response to UBB vertical loading. The study included small female, large female, and midsized male PMHS to evaluate the effect of both size and sex. Whole-body tests were conducted on a live blast driven rig to assess injury mechanisms under complex UBB conditions and the relationship between pelvis and lumbar responses. Isolated lumbar spine component tests were conducted using high-speed x-ray video to measure the fracture force and visualize the fracture propagation. Results suggest that there are differences between male and female UBB outcomes related to both sex and size. In whole-body tests, small females demonstrate a different injury pattern (pelvis fractures) than males (lumbar fractures), with large females exhibiting a mix of both. Mean fracture initiation forces in the lumbar component tests were different among the three PMHS groups, although the fracture propagation proved to be similar.

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Year

Entry

1970

Yamada H. Strength of Biological Materials. Evans FG, ed. Baltimore, MD: Williams & Wilkins Company; 1970.

1976

Padgaonkar AJ. Validation Study of a Three-Dimensional Crash Victim Simulator for Pedestrian-Vehicle Impact [PhD thesis]. Detroit, MI: Wayne State University; 1976.

2003

Mertz HJ, Irwin AL, Prasad P. Biomechanical and scaling bases for frontal and side impact injury assessment reference values. Stapp Car Crash J. 2003;47:155-188. SAE 2003-22-0009.

1989

Mertz HJ, Irwin AL, Melvin JW, Stalnaker RL, Beebe MS. Size, weight and biomechanical impact response requirements for adult size small female and large male dummies. In: Proceedings of the SAE International Congress & Exposition. February 27–March 3, 1989; Detroit, MI. Warrendale, PA: Society of Automotive Engineers. SAE 890756.

2015

Petitjean A, Trosseille X, Yoganandan N, Pintar FA. Normalization and scaling for human response corridors and development of injury risk curves. In: Yoganandan N, Nahum AM, Melvin JW, eds. Accidental Injury: Biomechanics and Prevention. 3rd ed. New York: Springer; 2015:769-792.