Evaluation of trabeculectomy blebs using 3-dimensional cornea and anterior segment optical coherence tomography.

OBJECTIVE To investigate the internal structures of trabeculectomy blebs using 3-dimensional cornea and anterior segment optical coherence tomography (3-D CAS OCT). DESIGN Observational case series. PARTICIPANTS Thirty-eight filtering blebs in 31 patients who had undergone trabeculectomy examined retrospectively. METHODS Intrableb structures were examined using 3-D CAS OCT. The blebs were classified clinically as successful (intraocular pressure [IOP] <18 mmHg without glaucoma medication) or failed. MAIN OUTCOME MEASURES Bleb structures were assessed in terms of the visibility of the drainage route, scleral flap, and microcysts. The length and height of the internal fluid-filled cavity, maximum and minimum bleb wall thickness, total bleb height, volumes of the internal fluid-filled cavity and hyporeflective area, and number of microcysts were analyzed. RESULTS Intrableb drainage route, scleral flap, and microcysts were observed in 92.1%, 94.7%, and 86.8% eyes, respectively. The IOP showed a significant negative correlation with horizontal and vertical length of the fluid-filled cavity (Spearman correlation coefficient [r(s)] = -0.634; P<0.0001; and r(s) = -0.539; P = 0.0008, respectively), height of the fluid-filled cavity (r(s) = -0.334; P = 0.031), maximum bleb wall thickness (r(s) = -0.491; P = 0.0023), total bleb height (r(s) = -0.629; P<0.0001), volume of the internal fluid-filled cavity (r(s) = -0.480; P = 0.0029), volume of hyporeflective area (r(s) = -0.443; P = 0.0056), and number of microcysts (r(s) = -0.451; P = 0.0045). There were 26 successful (64.8%) and 12 failed (31.6%) blebs. Significant differences were observed between these groups in IOP (P<0.0001), horizontal and vertical length of the fluid-filled cavity (P<0.0001 and P = 0.0019, respectively), height of the fluid-filled cavity (P = 0.0046), maximum bleb wall thickness (P = 0.0029), total bleb height (P = 0.0003), volume of the internal fluid-filled cavity (P = 0.0006), volume of hyporeflective area (P = 0.0020), and number of microcysts (P = 0.0025). CONCLUSIONS The internal aqueous humor outflow channel and scleral flap could be visualized, and the 3-D volume of the intrableb cavity was calculated using 3-D CAS OCT. The successful blebs exhibited a large internal fluid-filled cavity, an extensive hyporeflective area, and thicker bleb walls with more microcysts. FINANCIAL DISCLOSURE(S) The author(s) have no proprietary or commercial interest in any materials discussed in this article.

[1]  Toyohiko Yatagai,et al.  High-Speed, swept-source optical coherence tomography: a 3-dimensional view of anterior chamber angle recession. , 2006, Acta ophthalmologica Scandinavica.

[2]  J. Duker,et al.  Three-dimensional retinal imaging with high-speed ultrahigh-resolution optical coherence tomography. , 2005, Ophthalmology.

[3]  C. Teng,et al.  Histology and mechanism of filtering operations. , 1959, American journal of ophthalmology.

[4]  A. Kampik,et al.  In vivo confocal microscopy of filtering blebs after trabeculectomy. , 2006, Archives of ophthalmology.

[5]  A. Kampik,et al.  In Vivo Confocal Microscopy of Normal Conjunctiva and Conjunctivitis , 2006, Cornea.

[6]  F. Grehn,et al.  Classification of filtering blebs in trabeculectomy: biomicroscopy and functionality , 1998, Current opinion in ophthalmology.

[7]  Joseph A Izatt,et al.  Heterodyne swept-source optical coherence tomography for complete complex conjugate ambiguity removal. , 2005, Journal of biomedical optics.

[8]  F. Foster,et al.  Clinical use of ultrasound biomicroscopy. , 1991, Ophthalmology.

[9]  T. Yatagai,et al.  Three-dimensional and high-speed swept-source optical coherence tomography for in vivo investigation of human anterior eye segments. , 2005, Optics express.

[10]  Tin Aung,et al.  Imaging of trabeculectomy blebs using anterior segment optical coherence tomography. , 2007, Ophthalmology.

[11]  W. Green,et al.  Histologic characteristics of filtering blebs in glaucomatous eyes. , 1983, Archives of ophthalmology.

[12]  C. Baudouin,et al.  In vivo confocal microscopy study of blebs after filtering surgery. , 2005, Ophthalmology.

[13]  S. Yun,et al.  High-speed optical frequency-domain imaging. , 2003, Optics express.

[14]  Toyohiko Yatagai,et al.  Three-dimensional Anterior Segment Optical Coherence Tomography of Filtering Blebs After Trabeculectomy , 2008, Journal of glaucoma.

[15]  Christopher Kai-shun Leung,et al.  Analysis of bleb morphology after trabeculectomy with Visante anterior segment optical coherence tomography , 2006, British Journal of Ophthalmology.

[16]  Louis B. Cantor,et al.  Morphologic Classification of Filtering Blebs after Glaucoma Filtration Surgery: The Indiana Bleb Appearance Grading Scale , 2003, Journal of glaucoma.

[17]  J. D. de Boer,et al.  Large depth-high resolution full 3D imaging of the anterior segments of the eye using high speed optical frequency domain imaging. , 2007, Optics express.

[18]  Masahiko Usui,et al.  Three-Dimensional Optical Coherence Tomography of Granular Corneal Dystrophy , 2007, Cornea.

[19]  Y. Kitazawa,et al.  An ultrasound biomicroscopic study of filtering blebs after mitomycin C trabeculectomy. , 1995, Ophthalmology.

[20]  Piero Barboni,et al.  Filtering blebs imaging by optical coherence tomography , 2005, Clinical & experimental ophthalmology.

[21]  C Bunce,et al.  A Pilot Study of a System for Grading of Drainage Blebs after Glaucoma Surgery , 2004, Journal of glaucoma.