OBJECTIVE: Enophthalmos is a severe complication of primary reconstruction of orbital floor fractures. The goal of secondary reconstruction procedures is to restore symmetrical globe positions to recover function and aesthetics. The authors propose a new method of orbital floor reconstruction using a mirroring technique and a customized titanium mesh, printed using a direct metal laser-sintering method. METHODS: This reconstructive protocol involves 4 steps: mirroring of the healthy orbit at the affected site, virtual design of a patient-specific orbital floor mesh, CAM procedures for direct laser-sintering of the customized titanium mesh, and surgical insertion of the device. Using a computed tomography data set, the normal, uninjured side of the craniofacial skeleton was reflected onto the contralateral injured side, and a reconstructive orbital floor mesh was designed virtually on the mirrored orbital bone surface. The solid-to-layer files of the mesh were then manufactured using direct metal laser sintering, which resolves the shaping and bending biases inherent in the indirect method. An intraoperative navigation system ensured accuracy of the entire procedure. RESULTS: Clinical outcomes were assessed using 3dMD photogrammetry and computed tomography data in 7 treated patients. CONCLUSION: The technique described here appears to be a viable method to correct complex orbital floor defects needing delayed reconstruction. This study represents the first step in the development of a wider experimental protocol for orbital floor reconstruction using computer-assisted design-computer-assisted manufacturing technology.
OBJECTIVE: Enophthalmos is a severe complication of primary reconstruction of orbital floor fractures. The goal of secondary reconstruction procedures is to restore symmetrical globe positions to recover function and aesthetics. The authors propose a new method of orbital floor reconstruction using a mirroring technique and a customized titanium mesh, printed using a direct metal laser-sintering method. METHODS: This reconstructive protocol involves 4 steps: mirroring of the healthy orbit at the affected site, virtual design of a patient-specific orbital floor mesh, CAM procedures for direct laser-sintering of the customized titanium mesh, and surgical insertion of the device. Using a computed tomography data set, the normal, uninjured side of the craniofacial skeleton was reflected onto the contralateral injured side, and a reconstructive orbital floor mesh was designed virtually on the mirrored orbital bone surface. The solid-to-layer files of the mesh were then manufactured using direct metal laser sintering, which resolves the shaping and bending biases inherent in the indirect method. An intraoperative navigation system ensured accuracy of the entire procedure. RESULTS: Clinical outcomes were assessed using 3dMD photogrammetry and computed tomography data in 7 treated patients. CONCLUSION: The technique described here appears to be a viable method to correct complex orbital floor defects needing delayed reconstruction. This study represents the first step in the development of a wider experimental protocol for orbital floor reconstruction using computer-assisted design-computer-assisted manufacturing technology.
Authors: Sarah R Akkina; Aliya Shabbir; Annamarie Lahti; Raghu C Mudumbai; Christopher B Chambers; Kris S Moe; James O Phillips Journal: Facial Plast Surg Aesthet Med Date: 2020-05-22
Authors: Bruno Popić; Andrijana Kopić; Dubravka Holik; Kristijan Dinjar; Vlatko Kopić; Marko Matijević; Fran Popić Journal: Front Surg Date: 2022-09-05
Authors: Victor A Vasile; Sinziana Istrate; Raluca C Iancu; Roxana M Piticescu; Laura M Cursaru; Leopold Schmetterer; Gerhard Garhöfer; Alina Popa Cherecheanu Journal: Materials (Basel) Date: 2022-03-16 Impact factor: 3.623