Development of a finite element-based injury metric for pulmonary contusion, I: model development and validation

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Stitzel, Joel D.^1,2; Gayzik, F. Scott^1,2; Hoth, J. Jason²; Mercier, Jennifer²; Gage, H. Donald²; Morton, Kathryn A.³; Duma, Stefan M.¹; Payne, R. Mark²

Development of a finite element-based injury metric for pulmonary contusion, I: model development and validation

Stapp Car Crash J. 2005;49:271-289

Affiliations

¹Virginia Tech – Wake Forest University Center for Injury Biomechanics

²Wake Forest University School of Medicine

³University of Utah Health Sciences Center
Abstract and keywords

Pulmonary contusion is the most commonly identified thoracic soft tissue injury in an automobile crash and after blunt chest trauma and affects 10-17% of all trauma admissions. The mortality associated with pulmonary contusions is significant and is estimated to be 10-25%. Thus, there is a need to develop a finite element model based injury metric for pulmonary contusion for the purpose of predicting outcome. This will enable current and future finite element models of the lung to incorporate an understanding of how stress and strain may be related to contusion injuries.

This study utilizes 14 impacts onto male Sprague-Dawley rats. In 5 of these tests, a calibrated weight (46 g) is dropped from a height of 44 cm directly onto the lungs of intubated, anesthetized rats in situ . Contused volume is estimated from MicroPET scans of the lung and normalized on the basis of liver uptake of 18F-FDG. The lungs are scanned at 24 hours, 7 days, and 28 days (15 scans), and the contused volume is measured. In addition, 9 controlled mechanical tests on in situ rat lung are used for model development and validation.

Identical impacts are performed on a finite element model of the rat lung. The finite element model is developed from CT scans of normal rat and scaled to represent average rat lung volume. First principal strain is chosen as a candidate injury metric for pulmonary contusion. The volume of contused tissue at the three time points measured using PET is compared to the strain level achieved by a corresponding volume in the finite element model. For PET scans (n=5 scans per time point), the average contusion volume was 4.2 cm 3 at 24 hours, 2.8 cm 3 at 7 days, and 0.39 cm 3 at 28 days. These volumes were used to identify threshold peak first principal strain levels measured by the finite element model. Maximum first principal strain from the finite element model for the three volume levels (4.2, 2.8, and 0.39 cm 3 ) was 3.5%, 8.8%, and 35% strain, respectively. Furthermore, the lung model exhibited exponential decay in principal strain threshold as more of the lung volume was considered, correlating to the precise and well defined volume of the contusion as it healed.

The results of this study may be used to establish an injury metric to predict pulmonary contusion due to an impact to the lungs. The results may be used to improve finite element models of the human body, which may then be used to tune stiffnesses of interior components of automobiles and tune safety systems for maximum mitigation of this serious injury.

Keywords: thorax; finite element; model; lung; pulmonary; contusion; ARDS; injury metric; injury criteria; positron emission tomography
Links

PubMed: 17096278

SAE: 2005-22-0013

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2010	Kemper AR, Santago AC, Stitzel JD, Sparks JL, Duma SM. Biomechanical response of human liver in tensile loading. In: 54th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 17-20, 2010; Las Vegas, NV.15-26.
2011	Danelson KA, Chiles C, Thompson AB, Donadino K, Weaver AA, Stitzel JD. Correlating the extent of pulmonary contusion to vehicle crash parameters in near-side impacts. In: 55th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 3-5, 2011; Paris, France.217-230.
2011	Kemper A, Santago A, Sparks J, Thor C, Gabler HC, Stitzel J, Duma S. Multi-scale biomechanical characterization of human liver and spleen. In: Proceedings of the 22nd International Technical Conference on the Enhanced Safety of Vehicles (ESV). June 13-16, 2011; Washington, DC.
2011	Hallman JJ, Yoganandan N, Pintar FA. External measurements and visceral response in a cross-sectional torso impact model. In: Proceedings of the 39th International Workshop on Human Subjects for Biomechanical Research. 2011.
2008	Yuen KF, Cronin DS, Deng YC. Lung response and injury in side impact conditions. In: Proceedings of the 2008 International IRCOBI Conference on the Biomechanics of Impact. September 17-19, 2008; Bern, Switzerland.87-98.
2020	Ressi F, Kofler D, Sinz W, Tomasch E, Klug C. Key injury regions for passenger car drivers in frontal crashes: a comparison of results from IGLAD and finite element simulations using a human body model. In: Proceedings of the 2020 International IRCOBI Conference on the Biomechanics of Injury. 2020; Munich, Germany.137-155.
2008	Gayzik FS, Hoth JJ, Brownlee N, Stitzel JD. Quantitative histology of contused lung tissue with comparison to computed tomography. In: Proceedings of the 4th Ohio State University Injury Biomechanics Symposium. May 19-20, 2008; Columbus, OH.
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2011	Gayzik FS, Hoth JJ, Stitzel JD. Finite element–based injury metrics for pulmonary contusion via concurrent model optimization. Biomech Model Mechanobiol. 2011;10(4):505-520.
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2012	Hu J, Klinich KD, Reed MP, Kokkolaras M, Rupp JD. Development and validation of a modified Hybrid-III six-year-old dummy model for simulating submarining in motor-vehicle crashes. Med Eng Phys. June 2012;34(5):541-551.
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2008	Gayzik FS. Development of a Finite Element Based Injury Metric for Pulmonary Contusion [PhD thesis]. Winston-Salem, NC: Virginia Tech — Wake Forest University; December 2008.