PURPOSE: The authors have recently developed a high-resolution microscope-integrated spectral domain optical coherence tomography (MIOCT) device designed to enable OCT acquisition simultaneous with surgical maneuvers. The purpose of this report is to describe translation of this device from preclinical testing into human intraoperative imaging. METHODS: Before human imaging, surgical conditions were fully simulated for extensive preclinical MIOCT evaluation in a custom model eye system. Microscope-integrated spectral domain OCT images were then acquired in normal human volunteers and during vitreoretinal surgery in patients who consented to participate in a prospective institutional review board-approved study. Microscope-integrated spectral domain OCT images were obtained before and at pauses in surgical maneuvers and were compared based on predetermined diagnostic criteria to images obtained with a high-resolution spectral domain research handheld OCT system (HHOCT; Bioptigen, Inc) at the same time point. Cohorts of five consecutive patients were imaged. Successful end points were predefined, including ≥80% correlation in identification of pathology between MIOCT and HHOCT in ≥80% of the patients. RESULTS: Microscope-integrated spectral domain OCT was favorably evaluated by study surgeons and scrub nurses, all of whom responded that they would consider participating in human intraoperative imaging trials. The preclinical evaluation identified significant improvements that were made before MIOCT use during human surgery. The MIOCT transition into clinical human research was smooth. Microscope-integrated spectral domain OCT imaging in normal human volunteers demonstrated high resolution comparable to tabletop scanners. In the operating room, after an initial learning curve, surgeons successfully acquired human macular MIOCT images before and after surgical maneuvers. Microscope-integrated spectral domain OCT imaging confirmed preoperative diagnoses, such as full-thickness macular hole and vitreomacular traction, and demonstrated postsurgical changes in retinal morphology. Two cohorts of five patients were imaged. In the second cohort, the predefined end points were exceeded with ≥80% correlation between microscope-mounted OCT and HHOCT imaging in 100% of the patients. CONCLUSION: This report describes high-resolution MIOCT imaging using the prototype device in human eyes during vitreoretinal surgery, with successful achievement of predefined end points for imaging. Further refinements and investigations will be directed toward fully integrating MIOCT with vitreoretinal and other ocular surgery to image surgical maneuvers in real time.
PURPOSE: The authors have recently developed a high-resolution microscope-integrated spectral domain optical coherence tomography (MIOCT) device designed to enable OCT acquisition simultaneous with surgical maneuvers. The purpose of this report is to describe translation of this device from preclinical testing into human intraoperative imaging. METHODS: Before human imaging, surgical conditions were fully simulated for extensive preclinical MIOCT evaluation in a custom model eye system. Microscope-integrated spectral domain OCT images were then acquired in normal human volunteers and during vitreoretinal surgery in patients who consented to participate in a prospective institutional review board-approved study. Microscope-integrated spectral domain OCT images were obtained before and at pauses in surgical maneuvers and were compared based on predetermined diagnostic criteria to images obtained with a high-resolution spectral domain research handheld OCT system (HHOCT; Bioptigen, Inc) at the same time point. Cohorts of five consecutive patients were imaged. Successful end points were predefined, including ≥80% correlation in identification of pathology between MIOCT and HHOCT in ≥80% of the patients. RESULTS: Microscope-integrated spectral domain OCT was favorably evaluated by study surgeons and scrub nurses, all of whom responded that they would consider participating in human intraoperative imaging trials. The preclinical evaluation identified significant improvements that were made before MIOCT use during human surgery. The MIOCT transition into clinical human research was smooth. Microscope-integrated spectral domain OCT imaging in normal human volunteers demonstrated high resolution comparable to tabletop scanners. In the operating room, after an initial learning curve, surgeons successfully acquired human macular MIOCT images before and after surgical maneuvers. Microscope-integrated spectral domain OCT imaging confirmed preoperative diagnoses, such as full-thickness macular hole and vitreomacular traction, and demonstrated postsurgical changes in retinal morphology. Two cohorts of five patients were imaged. In the second cohort, the predefined end points were exceeded with ≥80% correlation between microscope-mounted OCT and HHOCT imaging in 100% of the patients. CONCLUSION: This report describes high-resolution MIOCT imaging using the prototype device in human eyes during vitreoretinal surgery, with successful achievement of predefined end points for imaging. Further refinements and investigations will be directed toward fully integrating MIOCT with vitreoretinal and other ocular surgery to image surgical maneuvers in real time.
Authors: Marcin Balicki; Jae-Ho Han; Iulian Iordachita; Peter Gehlbach; James Handa; Russell Taylor; Jin Kang Journal: Med Image Comput Comput Assist Interv Date: 2009
Authors: Justis P Ehlers; Yuankai K Tao; Sina Farsiu; Ramiro Maldonado; Joseph A Izatt; Cynthia A Toth Journal: Invest Ophthalmol Vis Sci Date: 2011-05-16 Impact factor: 4.799
Authors: Charles C Wykoff; Audina M Berrocal; Amy C Schefler; Stephen R Uhlhorn; Marco Ruggeri; Ditte Hess Journal: Ophthalmic Surg Lasers Imaging Date: 2010 Jan-Feb
Authors: Paul Hahn; Justin Migacz; Rachelle O'Connell; Ramiro S Maldonado; Joseph A Izatt; Cynthia A Toth Journal: Ophthalmic Surg Lasers Imaging Date: 2011-07
Authors: Robin Ray; David E Barañano; Jorge A Fortun; Bryan J Schwent; Blaine E Cribbs; Chris S Bergstrom; G Baker Hubbard; Sunil K Srivastava Journal: Ophthalmology Date: 2011-09-09 Impact factor: 12.079
Authors: Gyeong Woo Cheon; Berk Gonenc; Russell H Taylor; Peter L Gehlbach; Jin U Kang Journal: IEEE ASME Trans Mechatron Date: 2017-09-05 Impact factor: 5.303
Authors: Neel D Pasricha; Paramjit K Bhullar; Christine Shieh; Oscar M Carrasco-Zevallos; Brenton Keller; Joseph A Izatt; Cynthia A Toth; Sharon F Freedman; Anthony N Kuo Journal: J Pediatr Ophthalmol Strabismus Date: 2017-02-14 Impact factor: 1.402
Authors: Justis P Ehlers; Yasha S Modi; Paula E Pecen; Jeff Goshe; William J Dupps; Aleksandra Rachitskaya; Sumit Sharma; Alex Yuan; Rishi Singh; Peter K Kaiser; Jamie L Reese; Carmen Calabrise; Allison Watts; Sunil K Srivastava Journal: Ophthalmology Date: 2018-03-02 Impact factor: 12.079
Authors: Wolfgang Wieser; Wolfgang Draxinger; Thomas Klein; Sebastian Karpf; Tom Pfeiffer; Robert Huber Journal: Biomed Opt Express Date: 2014-08-06 Impact factor: 3.732