Anterior segment OCT (AS-OCT) has become invaluable for the diagnosis and management of glaucoma. First-generation instruments offered time-domain and spectral-domain OCT. Newer-generation swept-source OCT (SS-OCT) employs a longer wavelength of light (1,310 nm) and higher scan speeds (up to 100,000 A-scans per second) to provide improved axial resolution (5 µm). Currently available SS-OCT instruments include the Casia2 (Tomey), Anterion (Heidelberg Engineering), and Triton DRI (Topcon).
Its ability to image the angle, Schlemm canal, and trabecular meshwork gives AS-OCT a role in MIGS.1
THE PERIOPERATIVE UTILITY OF AS-OCT
Preoperative Evaluation
A comprehensive preoperative evaluation of the anterior segment is critical for identifying patients with an open angle who are suitable candidates for MIGS. The ability of AS-OCT to provide precise cross-sectional imaging of the angle facilitates the detection of structural variations in conjunction with traditional gonioscopy. AS-OCT can detect narrow angles, iridotrabecular contact, and areas of peripheral anterior synechiae. The newer-generation AS-OCT modalities use swept-source technology, giving them heightened sensitivity to detect even subtle anatomic abnormalities. The technology’s precision occasionally leads to overdiagnosis, however, making the careful interpretation of findings essential.2
Intraoperative Adjustments
AS-OCT has revolutionized MIGS by enabling real-time intraoperative imaging. With instruments such as the Artevo 800 (Carl Zeiss Meditec), surgeons can confirm an implant’s position and make immediate adjustments as needed. This precision reduces the likelihood of malpositioned devices, which can compromise surgical efficacy and postoperative IOP control. Repositioning devices during surgery reduces the risk of failed procedures.
A study found that intraoperative OCT allowed real-time visualization of an overimplanted iStent (Glaukos), with the flange observed to be flush against the trabecular meshwork.3 The same study described intraoperative OCT signs of an optimally placed Hydrus Microstent (Alcon). Specifically, the absence of the tram-track and knuckle signs indicated incorrect device positioning.
Postoperative Outcomes
AS-OCT can evaluate MIGS outcomes. In a prospective analysis, the protrusion of an iStent was associated with lower postoperative IOP compared to overimplanted devices.4
AS-OCT has also been used to evaluate the trabeculotomy opening size following Trabectome (MicroSurgical Technology) surgery. One study found no correlation between opening size and IOP reduction.5
In Liverpool, United Kingdom, AS-OCT has been used postoperatively to confirm the presence of and evaluate pores created in the trabecular meshwork with an excimer laser trabeculotomy (Elios, Elios Vision; Figure 1).
Figure 1. AS-OCT images of trabeculotomy pores created during excimer laser trabeculotomy. Pores are visible at the 3 (A) and 2 (B) clock positions in the nasal angle postoperatively.
All the aforementioned findings highlight the potential of AS-OCT to investigate whether specific structural changes achieved during surgery are predictive of clinical success.
In the postoperative setting, AS-OCT can be used to track gradual anatomic changes over time. This is particularly helpful for monitoring implant performance. For instance, AS-OCT can determine if a suprachoroidal implant is correctly positioned in the anterior chamber and monitor the size of the distal suprachoroidal space in correlation with clinical outcomes (Figure 2).
Figure 2. Postoperative AS-OCT images of a Miniject (iStar Medical) in situ in two patients. The length of the entire device (A). The anterior part of a device with the septations shown in the suprachoroidal space created (B).
1. Kan JT, Betzler BK, Lim SY, Ang BCH. Anterior segment imaging in minimally invasive glaucoma surgery - a systematic review. Acta Ophthalmol. 2022;100(3):e617-e634.
2. Nolan WP, See JL, Chew PT, et al. Detection of primary angle closure using anterior segment optical coherence tomography in Asian eyes. Ophthalmology. 2007;114(1):33-39.
3. Ang BCH, Betzler BK, Lim SY. Intraoperative optical coherence tomography for ab interno trabecular bypass glaucoma surgery. J Glaucoma. 2023;32(11):e151-e155.
4. Gillmann K, Bravetti GE, Mermoud A, Mansouri K. A prospective analysis of iStent Inject microstent positioning: Schlemm canal dilatation and intraocular pressure correlations. J Glaucoma. 2019;28(7):613-621.
5. Wecker T, Anton A, Neuburger M, Jordan JF, van Oterendorp C. Trabeculotomy opening size and IOP reduction after Trabectome surgery. Graefes Arch Clin Exp Ophthalmol. 2017;255(8):1643-1650.
6. Chen Z, Sun J, Li M, et al. Effect of age on the morphologies of the human Schlemm’s canal and trabecular meshwork measured with swept source optical coherence tomography. Eye (Lond). 2018;32(10):1621-1628.
7. Wang F, Shi G, Li X, et al. Comparison of Schlemm’s canal’s biological parameters in primary open-angle glaucoma and normal human eyes with swept source optical. J Biomed Opt. 2012;17(11):116008.
8. Johnstone M, Xin C, Tan J, Martin E, Wen J, Wang RK. Aqueous outflow regulation - 21st century concepts. Prog Retin Eye Res. 2021;83:100917.
