Numerical modeling of paintball impact ocular trauma: identification of progressive injury mechanisms.

PURPOSE: To create a computer-based numerical simulation model for comparison with empiric paintball-ocular ballistic study findings, allowing identification of the dynamic physical mechanisms (stress, strain, pressure) responsible for intraocular traumatic injury accompanying blunt ocular impact. Virtual experiments with numerical models could exploit mathematical "instrumentation" to facilitate internal observation impossible with physical experiments alone. METHODS: Models of human eye structures and orbit were implemented into the finite-volume Eulerian numerical hydrocode CTH. Numerical simulation results were compared with dynamic imaging and postimpact histopathology obtained during previous ballistic impact experiments on fresh porcine eyes impacted with paintballs. Forty numerical simulations and 59 impact experiments were conducted as part of the study. RESULTS: Time-lapse correlations showed the CTH models to be dynamically commensurate with orbital penetration and globe deformation measured from ballistic high-speed videos. CTH also predicted the types and levels of damage observed in detailed postimpact pathologic assessments of porcine specimens. High strain in the ciliary body and zonule corresponded with angle recession and lens displacement pathologically. Globe rupture was attained at the highest paintball impact velocities in both the porcine ballistic studies and CTH models, consistent with predicted dynamic intraocular pressures. The simulations also revealed that phenomena such as macular Berlin's edema, midperipheral retinoschisis, and choroidal and retinal detachment might be explained by focal dynamic pressure-wave reflection from the interior surface of the globe. CONCLUSIONS: Significant insight was gained regarding the physical mechanisms responsible for injury. CTH predictions corresponded closely with previous ballistic experimental results, adding intraocular detail otherwise unattainable.

Blunt eye trauma: empirical histopathologic paintball impact thresholds in fresh mounted porcine eyes.

PURPOSE: Ballistic studies were conducted using gelatin-embedded abattoir-fresh porcine eyes suspended within clear acrylic orbits to discern the energy required to produce specific ocular injuries. Paintball impact provides a robust ballistic model for isolating and quantifying the role of direct blunt force in ocular trauma. METHODS: Fifty-nine porcine orbital preparations received direct blows from 0.68 caliber (16-18 mm diameter/3.8 g) paintballs fired at impact velocities ranging from 26 to 97 meters per second (2-13.5 J). Five additional eyes not subjected to ballistic impact were also evaluated as controls. Impact energies were correlated with histopathologic damage. RESULTS: Minimum impact energies consistently producing damage in experimental eyes unobserved in control specimens were: 2 joules--posterior lens dislocation, zonulysis, capsular rupture, and choroidal detachment; 3.5 joules--moderate angle recession; 4 joules--anterior lens dislocation; 4.8 joules--peripapillary retinal detachment; 7 joules--severe angle recession, iridodialysis, and cyclodialysis; 7.5 joules--corneal stromal distraction; 9.3 joules--choroidal segmentation; and 10 joules--globe rupture. CONCLUSIONS: Impact thresholds correlating traumatic ocular pathology with impact energy followed a positive stepwise progression in severity with impact energies between 2 and 10 joules. Moderate angle recession commensurate with typical clinical traumatic glaucoma was not observed among control eyes, but occurred at relatively low impact energy of 3.5 joules among test eyes. Extensive disruption in and around the angle (iridodialysis/cyclodialysis) consistently occurred at energies >7 joules. Globe rupture required a minimum energy of 10 joules.