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Investigation on risk prediction of pedestrian head injury by real-world accidents

    Fan Li Affiliation
    ; Honggeng Li Affiliation
    ; Fuhao Mo Affiliation
    ; Sen Xiao Affiliation
    ; Zhi Xiao Affiliation

Abstract

Head injury is the most common and fatal injury in car-pedestrian accidents. Due to the lack of human test data, real-world accident data is useful for the research on the mechanism and tolerance of head injuries. The objective of the present work is to investigate pedestrian head-brain injuries through real car-pedestrian accidents and evaluate the existed injury criteria. Seven car-to-pedestrian accidents in China were selected from the IVAC (Investigation of Vehicle Accident in Changsha) database. Accident reconstructions using multi-body models were conducted to determine the kinematic parameters associated with the injury and were used to measure head injury criteria. Kinematic parameters were input into a finite element model to run simulations on the head-brain and car interface to determine levels of brain tissue stress, strain, and brain tissue injury criteria. A binary logistic regression model was used to determine the probability of head injury risk associated with AIS3+ injuries (Abbreviated Injury Scale). The results showed that head injury criteria using kinematic parameters can effectively predict injury risk of a pedestrians’ head skull. Regarding brain injuries, physical parameters like coup/countercoup pressure are more effective predictors. The results of this study can be used as the background knowledge for pedestrian friendly car design.

Keyword : head injury, traffic accident, pedestrian, injury criteria, logistic regression

How to Cite
Li, F., Li, H., Mo, F., Xiao, S., & Xiao, Z. (2019). Investigation on risk prediction of pedestrian head injury by real-world accidents. Transport, 34(3), 394-403. https://doi.org/10.3846/transport.2019.10410
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Jun 11, 2019
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References

Baumgartner, D. 2001. Mécanismes de lésion et limites de tolérance au choc de la tête humaine: simulations numériques et expérimentales de traumatismes crâniens. Thèse de doctorat, Université Louis Pasteur Strasbourg, 2001. (in French).

Boyd, C. R.; Tolson, M. A.; Copes, W. S. 1987. Evaluating trauma care: the TRISS method, The Journal of Trauma: Injury, Infection, and Critical Care 27(4): 370–378. https://doi.org/10.1097/00005373-198704000-00005

Dai, B.; Zhao, G.; Dong, L.; Yang, C. 2015. Mechanical characteristics for rocks under different paths and unloading rates under confining pressures, Shock and Vibration 2015: 578748. https://doi.org/10.1155/2015/578748

Dong, L.; Li, X.; Ma, C.; Zhu, W. 2013. Comparisons of logistic regression and Fisher discriminant classifier to seismic event identification, Disaster Advances 6(S4): 1–7.

EEVC. 1998. Improved Test Methods To Evaluate Pedestrian Protection Afforded By Passenger Cars. EEVC Working Group 17 Report. European Enhanced Vehicle-Safety Committee (EEVC). 98 p. Available from Internet: http://www.eevc.net/fileuploads/server/php/?file=WG17_Improved_test_methods_updated_sept_2002.pdf&download=1

Henn, H.-W. 1998. Crash tests and the head injury criterion, Teaching Mathematics and its Applications: an International Journal of the IMA 17(4): 162–170. https://doi.org/10.1093/teamat/17.4.162

Lissner, H. R.; Lebow, M.; Evans, F. G. 1960. Experimental studies on the relation between acceleration and intracranial pressure changes in man, Surgery, Gynecology & Obstetrics 111(3): 329–338.

Margulies, S. S.; Thibault, L. E. 1992. A proposed tolerance criterion for diffuse axonal injury in man, Journal of Biomechanics 25(8): 917–923. https://doi.org/10.1016/0021-9290(92)90231-O

Marjoux, D.; Baumgartner, D.; Deck, C.; Willinger, R. 2008. Head injury prediction capability of the HIC, HIP, SIMon and ULP criteria, Accident Analysis & Prevention 40(3): 1135–1148. https://doi.org/10.1016/j.aap.2007.12.006

Martinez, L.; Guerra, L. J.; Ferichola, G.; Garcia, A.; Yang, J. 2007. Stiffness corridors of the European fleet for pedestrian simulations, in 20th International Technical Conference on the Enhanced Safety of Vehicles (ESV), 16–21 June 2007, Lyon, France, 1–15.

Newman, J. A. 1986. A generalized acceleration model for brain injury threshold (GAMBIT), in Proceedings of the 1986 International IRCOBI Conference on the Biomechanics of Impact, 2–4 September 1986, Zurich, Switzerland, 121–132.

Newman, J. A.; Shewchenko, N.; Welbourne, E. 2000. A proposed new biomechanical head injury assessment function: the maximum power index, Stapp Car Crash Journal 44: 215–247.

NHTSA. 2006. Finite Element Model of Dodge Neon: Model Year 1996, Version 7. National Crash Analysis Center, National Highway Traffic Safety Administration (NHTSA), Washington, DC, US. Available from Internet: https://www.nhtsa.gov/crash-simulation-vehicle-models

Sun, D.-Z.; Andreiux, F.; Ockewitz, A.; Klamser, H.; Hogenmüller, J. 2005. Modeling of the failure behaviour of windscreens and component tests, in 5 European LS-DYNA Users’ Conference 2005, 25–26 May 2005, Birmingham, UK.

TA. 2014. Statistics of Road Traffic Accidents in P.R. of China 2000–2013. Traffic Administration (TA), Ministry of Public Security. Traffic Administration Press. 108 p. (in Chinese).

Takhounts, E. G.; Eppinger, R. H.; Campbell, J. Q.; Tannous, R. E.; Power, E. D.; Shook, L. S. 2003. On the development of the SIMon finite element head model, SAE Technical Paper 2003-22-0007. https://doi.org/10.4271/2003-22-0007

Ward, C.; Chan M.; Nahum, A. 1980. Intracranial pressure – a brain injury criterion, SAE Technical Paper 801304. https://doi.org/10.4271/801304

Xu, W.; Yang, J. 2008. Virtual test validation of human head model for injury assessment in traffic accidents, Automotive Engineering 30(2): 151–155. (in Chinese). https://doi.org/10.3321/j.issn:1000-680X.2008.02.013

Yanaoka, T.; Dokko, Y.; Takahashi, Y. 2015. Investigation on an injury criterion related to traumatic brain injury primarily induced by head rotation, SAE Technical Paper 2015-01-1439. https://doi.org/10.4271/2015-01-1439

Yang, J. 2005. Review of injury biomechanics in car-pedestrian collisions, International Journal of Vehicle Safety 1(1/2/3): 100–117. https://doi.org/10.1504/IJVS.2005.007540

Yang, J. K.; Lövsund, P.; Cavallero, C.; Bonnoit, J. 2000. A human-body 3D mathematical model for simulation of car-pedestrian impacts, Journal of Crash Prevention and Injury Control 2(2): 131–149. https://doi.org/10.1080/10286580008902559

Yang, J.-K.; Xu, W.; Wan, X.-M. 2005. Development and validation of a head-neck finite element model for the study of neck dynamic responses in car impacts, Journal of Hunan University (Natural Sciences) 32(2): 6–12. (in Chinese). https://doi.org/10.3321/j.issn:1000-2472.2005.02.002

Yao, J.; Yang, J.; Otte, D. 2008. Investigation of head injuries by reconstructions of real-world vehicle-versus-adult-pedestrian accidents, Safety Science 46(7): 1103–1114. https://doi.org/10.1016/j.ssci.2007.06.021

Zhang, L.; Yang, K. H.; King, A. I. 2004. A proposed injury threshold for mild traumatic brain injury, Journal of Biomechanical Engineering 126(2): 226–236. https://doi.org/10.1115/1.1691446

Zoubir, A. M.; Boashash, B. 1998. The bootstrap and its application in signal processing, IEEE Signal Processing Magazine 15(1): 56-76. https://doi.org/10.1109/79.647043