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Journal Article


Panzer MB, Bass CR, Rafaels KA, Shridharani J, Capehart BP. J. Trauma 2013; ePub(ePub): ePub.


From the Department of Biomedical Engineering (M.B.P., C.R.D.B., J.S.), Duke University, Durham, North Carolina; Center for Applied Biomechanics (K.A.R.), University of Virginia, Charlottesville, Virginia; OEF/OIF Veterans Program and Mental Health Service Line (B.P.C.), Durham VA Medical Center, Durham, North Carolina; and Department of Psychiatry and Behavioral Sciences (B.P.C.), Duke University School of Medicine, Durham, North Carolina.


(Copyright © 2013, Lippincott Williams and Wilkins)






BACKGROUND:: The widespread use of explosives by modern insurgents and terrorists has increased the potential frequency of blast exposure in soldiers and civilians. This growing threat highlights the importance of understanding and evaluating blast injury risk and the increase of injury risk from exposure to repeated blast effects.

METHODS:: Data from more than 3,250 large animal experiments were collected from studies focusing on the effects of blast exposure. The current study uses 2,349 experiments from the data collection for analysis of the primary blast injury and survival risk for both long- and short-duration blasts, including the effects from repeated exposures. A piecewise linear logistic regression was performed on the data to develop survival and injury risk assessment curves.

RESULTS:: New injury risk assessment curves uniting long- and short-duration blasts were developed for incident and reflected pressure measures and were used to evaluate the risk of injury based on blast overpressure, positive-phase duration, and the number of repeated exposures. The risk assessments were derived for three levels of injury severity: nonauditory, pulmonary, and fatality. The analysis showed a marked initial decrease in injury tolerance with each subsequent blast exposure. This effect decreases with increasing number of blast exposures.

CONCLUSIONS:: The new injury risk functions showed good agreement with the existing experimental data and provided a simplified model for primary blast injury risk. This model can be used to predict blast injury or fatality risk for single exposure and repeated exposure cases and has application in modern combat scenarios or in setting occupational health limits.

Language: en


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