Force necessary to fracture the orbital floor

• Published in: Ophthalmic plastic and reconstructive surgery Vol. 6; no. 3; p. 211
• Main Authors: Green, Jr, R P, Peters, D R, Shore, J W, Fanton, J W, Davis, H
• Format: Journal Article
• Language: English
• Published: United States 1990
• Subjects: Animals; Biomechanical Phenomena; Eye Injuries - pathology; Eye Injuries - physiopathology; Macaca fascicularis; Orbital Fractures - pathology; Orbital Fractures - physiopathology; Rupture
• ISSN: 0740-9303
• DOI: 10.1097/00002341-199009000-00012

Current thought on the pathophysiology of orbital wall fractures postulates either a "hydraulic" or a "buckling" mechanism. Evidence from cadaver, dried skull, and theoretical model studies supports both theories. No in vivo data, human or nonhuman primate, are available that quantitate the force necessary to fracture the orbital floor by either of the two mechanisms. We developed an apparatus that delivers quantifiable force only to the globe, without occluding the orbital opening or striking the orbital rim. We used it on 11 anesthetized Macaca fascicularis monkeys. Following a single bilateral application, the orbits were exenterated, and the orbital walls and orbital contents were examined to determine the extent of injuries. Fractures were described, diagrammed, and photographed. Fracture of the orbital floor was consistently produced at and above a force of 2.08 J. Posterior ruptures of five eyes occurred over the same range. We provide the first accurate measurements of the force required to produce orbital blow-out fractures in a live primate model. We show that orbital floor fractures can occur at low energies with direct ocular trauma only ("pure" hydraulic mechanism). Orbital wall fractures failed to protect the globe from rupture in 23% of cases.