Page 84 - JSOM Winter 2021
P. 84
8. Bush JA, Jensen WN, Cartwright GE, Wintrobe MM. Blood vol- 14. Lau VK, Viano DC. Influence of impact velocity and chest com-
ume studies in normal and anemic swine. Am J Physiol. 1955;181 pression on experimental pulmonary injury severity in rabbits. J
(1):9–14. Trauma. 1981;21(12):1022–1028.
9. Gayzik FS, Hoth JJ, Stitzel JD. Finite element-based injury met- 15. Rice DA. Sound speed in pulmonary parenchyma. J Appl Physiol.
rics for pulmonary contusion via concurrent model optimization. 1983;54(1):304–308.
Biomech Model Mechanobiol. 2011;10(4):505–520. 16. Melton SM, Davis KA, Moomey CB, F. Mediator-dependent sec-
10. Relja B, Yang B, Bundkirchen K, et al. Different experimental ondary injury after unilateral blunt thoracic trauma. Shock Au-
multiple trauma models induce comparable inflammation and or- gusta Ga 1999;11(6):396–402.
gan injury. Sci Rep. 2020;10(1):20185. 17. Denk S, Weckbach S, Eisele P, et al. Role of hemorrhagic shock in
11. Pape H-C, Lefering R, Butcher N, et al. The definition of pol- experimental polytrauma. Shock. 2018;49(2):154–163.
ytrauma revisited: An international consensus process and pro- 18. Braun CK, Kalbitz M, Halbgebauer R, et al. Early structural
posal of the new “Berlin definition.” J Trauma Acute Care Surg. changes of the heart after experimental polytrauma and hemor-
2014;77(5):780–786. rhagic shock. PLoS One. 2017;12(10):e0187327.
12. Yang B, Bundkirchen K, Krettek C, et al. Traumatic injury pat- 19. Lichte P, Weber C, Sellei RM, et al. Are bilateral tibial shaft frac-
tern is of equal relevance as injury severity for experimental (poly) tures associated with an increased risk for adverse outcome? In-
trauma modeling. Sci Rep. 2019;9(1):5706. jury. 2014;45(12):1985–1989.
13. Viano DC, Lau IV. A viscous tolerance criterion for soft tissue
injury assessment. J Biomech. 1988;21(5):387–399.
82 | JSOM Volume 21, Edition 4 / Winter 2021
