TY - JOUR
T1 - Unprocessed real-time imaging of vitreoretinal surgical maneuvers using a microscope-integrated spectral-domain optical coherence tomography system
AU - Hahn, Paul
AU - Migacz, Justin
AU - O'Connell, Rachelle
AU - Izatt, Joseph A.
AU - Toth, Cynthia A.
N1 - Funding Information:
Supported by the Heed Ophthalmic Foundation (PH), NIH: 1UL1 RR024128-01; 1R21 EY019411 Dr. Toth receives research support through equipment loan from Bioptigen, and has potential for royalties for OCT-related technology licensed by Duke to Bioptigen. Dr. Toth also receives royalties for surgical technology licensed by Duke to Alcon Laboratories. Duke University has an equity interest in Bioptigen. Dr. Izatt is a co-founder of Bioptigen, Inc., and has corporate, intellectual property, and equity interests in this company.
PY - 2013/1
Y1 - 2013/1
N2 - Background: We have recently developed a microscope-integrated spectral-domain optical coherence tomography (MIOCT) device towards intrasurgical cross-sectional imaging of surgical maneuvers. In this report, we explore the capability of MIOCT to acquire real-time video imaging of vitreoretinal surgical maneuvers without post-processing modifications. Methods: Standard 3-port vitrectomy was performed in human during scheduled surgery as well as in cadaveric porcine eyes. MIOCT imaging of human subjects was performed in healthy normal volunteers and intraoperatively at a normal pause immediately following surgical manipulations, under an Institutional Review Board-approved protocol, with informed consent from all subjects. Video MIOCT imaging of live surgical manipulations was performed in cadaveric porcine eyes by carefully aligning B-scans with instrument orientation and movement. Inverted imaging was performed by lengthening of the reference arm to a position beyond the choroid. Results: Unprocessed MIOCT imaging was successfully obtained in healthy human volunteers and in human patients undergoing surgery, with visualization of post-surgical changes in unprocessed single B-scans. Real-time, unprocessed MIOCT video imaging was successfully obtained in cadaveric porcine eyes during brushing of the retina with the Tano scraper, peeling of superficial retinal tissue with intraocular forceps, and separation of the posterior hyaloid face. Real-time inverted imaging enabled imaging without complex conjugate artifacts. Conclusions: MIOCT is capable of unprocessed imaging of the macula in human patients undergoing surgery and of unprocessed, real-time, video imaging of surgical maneuvers in model eyes. These capabilities represent an important step towards development of MIOCT for efficient, real-time imaging of manipulations during human surgery.
AB - Background: We have recently developed a microscope-integrated spectral-domain optical coherence tomography (MIOCT) device towards intrasurgical cross-sectional imaging of surgical maneuvers. In this report, we explore the capability of MIOCT to acquire real-time video imaging of vitreoretinal surgical maneuvers without post-processing modifications. Methods: Standard 3-port vitrectomy was performed in human during scheduled surgery as well as in cadaveric porcine eyes. MIOCT imaging of human subjects was performed in healthy normal volunteers and intraoperatively at a normal pause immediately following surgical manipulations, under an Institutional Review Board-approved protocol, with informed consent from all subjects. Video MIOCT imaging of live surgical manipulations was performed in cadaveric porcine eyes by carefully aligning B-scans with instrument orientation and movement. Inverted imaging was performed by lengthening of the reference arm to a position beyond the choroid. Results: Unprocessed MIOCT imaging was successfully obtained in healthy human volunteers and in human patients undergoing surgery, with visualization of post-surgical changes in unprocessed single B-scans. Real-time, unprocessed MIOCT video imaging was successfully obtained in cadaveric porcine eyes during brushing of the retina with the Tano scraper, peeling of superficial retinal tissue with intraocular forceps, and separation of the posterior hyaloid face. Real-time inverted imaging enabled imaging without complex conjugate artifacts. Conclusions: MIOCT is capable of unprocessed imaging of the macula in human patients undergoing surgery and of unprocessed, real-time, video imaging of surgical maneuvers in model eyes. These capabilities represent an important step towards development of MIOCT for efficient, real-time imaging of manipulations during human surgery.
KW - Intraoperative
KW - Intrasurgical
KW - Microscope-integrated
KW - OCT
KW - Optical coherence tomography
KW - Real-time
KW - Unprocessed
KW - Vitreoretinal surgery
UR - http://www.scopus.com/inward/record.url?scp=84872356849&partnerID=8YFLogxK
U2 - 10.1007/s00417-012-2052-2
DO - 10.1007/s00417-012-2052-2
M3 - Review article
C2 - 22585009
AN - SCOPUS:84872356849
SN - 0721-832X
VL - 251
SP - 213
EP - 220
JO - Graefe's Archive for Clinical and Experimental Ophthalmology
JF - Graefe's Archive for Clinical and Experimental Ophthalmology
IS - 1
ER -