A nonlinear finite element model of the eye with experimental validation for the prediction of globe rupture

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Stitzel, Joel D.¹; Duma, Stefan M.¹; Cormier, Joseph M.¹; Herring, Ian P.¹

A nonlinear finite element model of the eye with experimental validation for the prediction of globe rupture

Stapp Car Crash J. 2002;46:81-102

Affiliations

¹Virginia Tech, Impact Biomechanics Laboratory
Abstract and keywords

Over 2.4 million eye injuries occur each year in the US, with over 30,000 patients left blind as a result of the trauma. The majority of these injuries occur in automobile crashes, military operations and sporting activities. This paper presents a nonlinear finite element model of the eye and the results of 22 experiments using human eyes to validate for globe rupture injury prediction. The model of the human eye consists of the cornea, sclera, lens, ciliary body, zonules, aqueous humor and vitreous body. Lagrangian membrane elements are used for the cornea and sclera, Lagrangian bricks for the lens, ciliary, and zonules, and Eulerian brick elements comprise the aqueous and vitreous. Nonlinear, isotropic material properties of the sclera and cornea were gathered from uniaxial tensile strip tests performed up to rupture. Dynamic modeling was performed using LS-Dyna. Experimental validation tests consisted of 22 tests using three scenarios: impacts from foam particles, BB's, and baseballs onto fresh eyes used within 24 hours postmortem. The energies of the projectiles were chosen so as to provide both globe rupture and no rupture tests. Displacements of the eye were recorded using high speed color video at 7100 frames per second. The matched simulations predicted rupture of the eye when rupture was seen in the BB and baseball tests, and closely predicted displacements of the eye for the foam tests. Globe rupture has previously been shown to occur at peak stresses of 9.4 MPa using the material properties included in the model. Because of dynamic effects and improvements in boundary conditions resulting from a more realistic modeling of the fluid in the anterior and posterior chambers, the stresses can be much higher than those previously predicted, with the globe remaining intact. The model is empirically verified to predict globe rupture for stresses in the corneoscleral shell exceeding 23 MPa, and local dynamic pressures exceeding 2.1 MPa. The model can be used as a predictive aid to reduce the burden of eye injury, and can serve as a validated model to predict globe rupture.

Keywords: Eye; Modeling; Rupture; Injury; Cornea; Sclera; Limbus
Links

PubMed: 17096220

SAE: 2002-22-0005

Cited Works (8)

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Cited By (27)

Year	Entry
2012	Duma SM, Bisplinghoff JA, Senge DM, McNally C, Alphonse VD. Evaluating the risk of eye injuries: intraocular pressure during high speed projectile impacts. Curr Eye Res. January 2012;37(1):43-49.
2003	Hansen GA, Stitzel JD, Duma SM. Incidence of elderly eye injuries in automobile crashes: the effects of lens stiffness as a function of age. In: 47th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). September 22-24, 2003; Lisbon, Portugal.147-163.
2004	Kennedy EA, Voorhies KD, Herring IP, Rath AL, Duma SM. Prediction of severe eye injuries in automobile accidents: static and dynamic rupture pressure of the eye. In: 48th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). September 13-15, 2004; Key Biscayne, FL.165-179.
2006	Gayzik FS, Bostrom O, Örtenwall P, Duma SM, Stitzel JD. An experimental and computational study of blunt carotid artery injury. In: 50th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 16-18, 2006; Chicago, IL.13-32.
2003	Duma SM, Jernigan MV, Stitzel JD, Herring IP. Eye injury incidence and mechanisms in frontal automobile crashes. In: Proceedings of the 18th International Technical Conference on the Enhanced Safety of Vehicles (ESV). May 19-22, 2003; Nagoya, Japan.
2005	Kennedy EA, Bonivtch AR, Herring IP, McNally C, Manoogian SJ, Stitzel JD, Duma SM. Effects of the extraocular muscles on the response of the human eye under static and dynamic loading conditions. In: Proceedings of the 33rd International Workshop on Human Subjects for Biomechanical Research. 2005.1-9.
2008	Bisplinghoff JA, McNally C, Herring IP, Brozoski FT, Stitzel JD, Duma SM. High rate internal pressurization of the human eye to determine dynamic material properties. In: Proceedings of the 36th International Workshop on Human Subjects for Biomechanical Research. November 2, 2008; San Antonio, TX.
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.
2016	Nadarasa J, Deck C, Meyer F, Bourdet N, Raul JS, Willinger R. Infant eye finite‐element model for injury analysis. In: Proceedings of the 2016 International IRCOBI Conference on the Biomechanics of Injury. September 14-16, 2016; Malaga, Spain.315-325.
2008	Bisplinghoff JA, McNally C, Herring IP, Brozoski FT, Duma SM. High rate internal pressurization of the human eye to determine dynamic material properties. In: Proceedings of the 4th Ohio State University Injury Biomechanics Symposium. May 19-20, 2008; Columbus, OH.
2005	Stitzel JD, Gayzik FS, Hoth JJ, Mercier J, Gage HD, Morton KA, Duma SM, Payne RM. Development of a finite element-based injury metric for pulmonary contusion, I: model development and validation. Stapp Car Crash J. 2005;49:271-289. SAE 2005-22-0013.
2006	Kennedy EA, Ng TP, McNally C, Stitzel JD, Duma SM. Risk functions for human and porcine eye rupture based on projectile characteristics of blunt objects. Stapp Car Crash J. 2006;50:651-671. SAE 2006-22-0026.
2007	Kennedy EA, Inzana JA, McNally C, Duma SM, Depinet PJ, Sullenberge KH, Morgan CR, Brozosk FT. Development and validation of a synthetic eye and orbit for estimating the potential for globe rupture due to specific impact conditions. Stapp Car Crash J. 2007;51:381-400. SAE 2007-22-0016.
2014	Golman AJ, Danelson KA, Miller LE, Stitzel JD. Injury prediction in a side impact crash using human body model simulation. Accid Anal Prev. March 2014;64:1-8.
2011	Danelson KA, Bolte JH, Stitzel JD. Assessing astronaut injury potential from suit connectors using a human body finite element model. Aviat Space Environ Med. 2011;82(2):79-86.
2018	Rau A, Lovald ST, Nissman S, McNulty J, Ochoa JA, Baldwinson M. The mechanics of corneal deformation and rupture for penetrating injury in the human eye. Injury. February 2018;49(2):230-235.
2005	Duma SM, Ng TP, Kennedy EA, Stitzel JD, Herring IP, Kuhn F. Determination of significant parameters for eye injury risk from projectiles. J Trauma. October 2005;59(4):960-964.
2017	Shedd DF. Ocular Injury Following Primary Blast Exposure [PhD thesis]. University of Utah; December 2017.
2021	Knaus KR. Form and Function Relationships Governing Complex Muscle-Soft Tissue Interactions Revealed With 3D Modeling: Applications to Aging [PhD thesis]. Charlottesville, VA: University of Virginia; May 2021.
2009	Yuen KF. The Development of a Numerical Human Body Model for the Analysis of Automotive Side Impact Lung Trauma [Master's thesis]. University of Waterloo; 2009.
2003	Voorhies KD. Static and Dynamic Stress/strain Properties for Human and Porcine Eyes [Master's thesis]. Virginia Polytechnic Institute and State University; April 22, 2003.
2005	Rath AL. The Effects of Extraocular Muscles on Eye Biomechanics [Master's thesis]. Virginia Polytechnic Institute and State University; April 22, 2005.
2007	Kennedy EA. The Development and Validation of a Biofidelic Synthetic Eye for the Facial and Ocular Countermeasure Safety (FOCUS) Headform [PhD thesis]. Virginia Polytechnic Institute and State University; 2007.
2012	Alphonse VD. Injury Biomechanics of the Human Eye During Blunt and Blast Loading [Master's thesis]. Virginia Polytechnic Institute and State University; March 26, 2012.
2012	Daniel RW II. Head Acceleration Measurements in Helmet-Helmet Impacts and the Youth Population [Master's thesis]. Virginia Polytechnic Institute and State University; April 16, 2012.
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.
2015	Gaewsky J. Driver Injury Metric and Risk Variability as a Function of Occupant Position in Real World Motor Vehicle Crashes [Master's thesis]. Winston-Salem, NC: Wake Forest University; May 2015.