Comparison of Hybrid III child test dummies to pediatric PMHS in blunt thoracic impact response

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Parent, D. P.¹; Crandall, J. R.¹; Bolton, J. R.¹; Bass, C. R.²; Ouyang, J.³; Lau, S. H.¹

Comparison of Hybrid III child test dummies to pediatric PMHS in blunt thoracic impact response

Traffic Inj Prev. 2010;11(4):399-410

Affiliations

¹Center for Applied Biomechanics, University of Virginia, Charlottesville, Virginia

²Injury and Orthopedics Biomechanics Laboratory, Department of Biomedical Engineering, Duke University, Durham, North Carolina

³Department of Anatomy, Southern Medical University, TongHe, GuangZhou, China
Abstract and keywords

The limited availability of pediatric biomechanical impact response data presents a significant challenge to the development of child dummies. In the absence of these data, the development of the current generation of child dummies has been driven by scaling of the biomechanical response requirements of the existing adult test dummies. Recently published pediatric blunt thoracic impact response data provide a unique opportunity to evaluate the efficacy of these scaling methodologies. However, the published data include several processing anomalies and nonphysical features. These features are corrected by minimizing instrumentation and processing error to improve the fidelity of the individual force-deflection responses. Using these data, biomechanical impact response corridors are calculated for a 3-year-old child and a 6-year-old child. These calculated corridors differ from both the originally published postmortem human subject (PMHS) corridors and the impact response requirements of the current child dummies. Furthermore, the response of the Hybrid III 3-year-old test dummy in the same impact condition shows a similar deflection but a significantly higher force than the 3-year-old corridor. The response of the Hybrid III 6-year-old dummy, on the other hand, correlates well with the calculated 6-year-old corridor. The newly developed 3-year-old and 6-year-old blunt thoracic impact response corridors can be used to define data-driven impact response requirements as an alternative to scaling-driven requirements.

Keywords: Cadavers; Chest injury; Child safety; Children; Crash dummies; Impact responses
Links

DOI: 10.1080/15389588.2010.486430

PubMed: 20730687

WoS: 000281167600009

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Cited By (5)

Year	Entry
2011	Jiang B, Mao H, Wagner C, Cao L, Yang KH. Development of a 10‐year‐old pediatric thorax finite element model validated against cardiopulmonary resuscitation data. In: Proceedings of the 2011 International IRCOBI Conference on the Biomechanics of Injury. September 14-16, 2011; Krakow, Poland.206-209.
2017	Murach MM, Kang Y-S, Stammen J, Moorhouse K, Bolte JH IV, Agnew AM. A preliminary exploration of contribution of the individual rib to dynamic response of the human thorax. In: Proceedings of the 13th Ohio State University Injury Biomechanics Symposium. May 21-23, 2017; Columbus, OH.
2018	Agnew AM, Murach MM, Dominguez VM, Sreedhar A, Misicka E, Harden A, Bolte JH IV, Kang Y-S, Stammen J, Moorhouse K. Sources of variability in structural bending response of pediatric and adult human ribs in dynamic frontal impacts. Proceedings of the Stapp Car Crash Conference. November 2018;62:119-192.
2014	Jiang B, Cao L, Mao H, Wagner C, Marek S, Yang KH. Development of a 10-year-old paediatric thorax finite element model validated against cardiopulmonary resuscitation data. Comput Methods Biomech Biomed Eng. 2014;17(11):1185-1197.
2017	Murach MM. The Contribution of the Individual Rib to Thoracic Response Under Dynamic Loading Conditions: A Preliminary Hierarchical Approach [Master's thesis]. The Ohio State University; 2017.