Abstract
The technology of optical coherence tomography (OCT) has evolved rapidly from time-domain to spectral-domain and swept-source OCT over the recent years. OCT has become an important tool for assessment of the anterior chamber angle and detection of angle closure. Improvement in image resolution and scan speed of OCT has facilitated a more detailed and comprehensive analysis of the anterior chamber angle. It is now possible to examine Schwalbe's line and Schlemm's canal along with the scleral spur. High-speed imaging allows evaluation of the angle in 360°. With three-dimensional reconstruction, visualization of the iris profiles and the angle configurations is enhanced. This article summarizes the development and application of OCT for anterior chamber angle measurement, detection of angle closure, and investigation of the pathophysiology of primary angle closure.
Main
Although gonioscopy is an indispensible technique to visualize the angle structures and estimate the angle width, objective and reproducible measurement of the dimensions of the anterior chamber angle can only be obtained with cross-sectional imaging devices from technologies such as ultrasound biomicroscopy (UBM) and optical coherence tomography (OCT). OCT has a number of advantages over UBM for anterior chamber angle imaging. OCT is a non-contact technique, has a higher image resolution, and is more precise in locating the position of interest for evaluation compared with UBM. It is recognized, however, that UBM has a unique role in visualizing the ciliary body. Although early generations of OCT were designed for imaging the macula and the optic disc, commercially available time-domain and spectral-domain models have been developed for anterior segment imaging. Visualization of the anterior chamber angle not only augments the diagnostic performance to detect a narrow angle and angle closure, but also improves our understanding of the pathophysiology of primary angle closure. This article provides an overview and update on the development and application of OCT for anterior chamber angle imaging.
The time-domain OCT
Since the introduction of the prototype in 1991,1 OCT has become an important tool in diagnosing macular diseases and glaucoma. Yet, only a few studies attempted to evaluate the anterior chamber angle in the 90s. Izatt et al2 reported the use of an OCT with a compact 830 nm superluminescent diode light source mounted on a standard slit-lamp biomicroscopy to image the anterior segment. It took ∼6 s to capture an area of 7 × 4.4 mm with a resolution of 200 × 500 pixels. Limited by a relatively low-image resolution, the details of the angle structures could not be clearly discerned. The third generation of OCT, the Stratus OCT (Carl Zeiss Meditec, Dublin, CA, USA), was commercially available in 2002. It has a faster scan speed (400 A-scans per s) and a higher axial resolution (10 μm) compared with the early OCT versions, including the prototype OCT, OCT 1 (Carl Zeiss Meditec), and OCT 2000 (Carl Zeiss Meditec). Leung et al illustrated the application of the Stratus OCT to investigate the dynamic changes of angle configurations in patients with primary angle closure, plateau iris configuration, and phacomorphic glaucoma.3 Widening of the angle and flattening of the iris were demonstrated after laser iridotomy and argon laser peripheral iridoplasty (Figure 1a and b). Similar observation was subsequently reported with other OCT systems specifically designed for anterior segment imaging.4, 5, 6 Although the configuration of the peripheral iris in relation to scleral–corneal junction could be examined with the Stratus OCT, the scleral spur, an anatomical landmark for measurement of the angle width and evaluation of angle closure, was not visible. The relatively short wavelength of the super luminescent diode (820 nm) in the Stratus OCT limits tissue penetration and scattering at the limbus impedes detailed analysis of the angle.
The Visante OCT and the SL-OCT
Two commercially available anterior segment OCT systems, the Visante OCT (Carl Zeiss Meditec) and the SL-OCT (Heidelberg Engineering, GmbH, Dossenheim, Germany), were, respectively, introduced in 2005 and 2006. With a wavelength of 1310 nm, both instruments showed an improvement of tissue penetration through the sclera (Figure 1c and d). The instrument specifications are similar between the two OCT systems (Table 1 ). Both OCTs are capable of imaging the anterior segment with dimensions of 15–16 mm in width and 6–7 mm in depth and an axial resolution of approximately 18–25 μm. A major difference between the two devices is their scan speed, which is 2000 A-scans per s for Visante OCT, and 200 A-scans per s for SL-OCT. With a line scan of 256 and 215 A-scans, each image frame takes 0.13 and 1.08 s for Visante OCT and SL-OCT, respectively. Another difference is that the Visante OCT has an internal fixation target to adjust for subject's refraction. Correction of refractive error is essential to minimize the variability of pupil size and lens position secondary to accommodation of the eye on measurement of the angle.
Visibility of the scleral spur in anterior segment OCT imaging
Precise location of the scleral spur is a pre-requisite for reliable measurement of the angle. Parameters including the angle-opening distance (AOD), trabecular iris angle (TIA), angle recess area (ARA), and trabecular iris space area (TISA) have been widely adopted to measure the angle dimensions and all of them are measured with reference to the scleral spur (Figure 2).7, 8 However, the scleral spur may not always be visible even with the anterior segment OCT. In a clinic-based study, including 502 participants aged 50 years or older, Sakata et al9 showed the scleral spur was detected in 72% of the Visante OCT images and that the superior and inferior quadrants were less detectable compared with the nasal and temporal quadrants. Using an ordinal scale to grade the visibility of the scleral spur (2=clear visibility, 1=moderate visibility, 0=not detectable) at the 12 clock hours imaged by the Visante OCT, Liu et al10 showed that the inferior quadrant at 6 o’clock had the worst visibility of the scleral spur (mean scleral spur visibility score=1.05±0.49), whereas the scleral spur was best visualized in the nasal quadrant at 3 o’clock (mean scleral spur visibility score=1.66±0.46). Methods for measurement of the angle independent of the scleral spur have been proposed. Leung et al11 investigated an automated edge detection algorithm to identify the outlining boundaries of the iris and the scleral-corneal junction at the anterior chamber angle. By fitting the scleral-corneal junction and the iris surface with two regression lines, the angle dimension can be measured. This algorithm, however, may not work well in eyes with a deep angle recess. With the advent of spectral-domain OCT, the angle structures can be examined even greater detail. Schwalbe's line and Schlemm's canal can now be detected with spectral-domain OCT (Figure 3).12 These structures could serve as useful landmarks to quantify the angle.
Reliability of anterior segment OCT for measurement of the angle
The anterior chamber angle can be outlined cross-sectionally by the junction formed by the scleral-corneal junction, the ciliary body and the peripheral iris. As the configurations of iris and ciliary body vary with lighting condition and accommodation of the eye, the dimensions of the angle can only be measured reproducibly after these covariates have been adjusted. Imaging the anterior chamber angle in the dark is critical to detect angle closure. It has been shown that the angle width is inversely proportional to the pupil size and that the diagnosis of angle-closure could be missed if assessment is not performed in the dark.13 Likewise, changes in pupil size and lens position during accommodation of the eye can also influence the evaluation of the angle.
Previous studies have shown good repeatability and reproducibility for measurement of AOD, TISA, ARA, and TIA with anterior segment OCT.14, 15, 16, 17, 18 With the lighting condition standardized and the refractive error corrected using an internal fixation target, the intra-session coefficient of variation of the angle width measured with the Visante OCT was ≤7% and the inter-session coefficient variation was ≤10%.15 The SL-OCT was equally reliable for measurement of the angles. In a study comparing angle measurements between Visante OCT and SL-OCT, the inter-observer coefficient of variation ranged between 4.4 and 7.8%, and between 4.9 and 7.0%, respectively.17 Nevertheless, the measurement agreement for the two instruments is poor. The spans of 95% limits of agreement of the nasal/temporal angle measurements between the instruments were 437/531 μm, 0.174/0.186 mm2, and 25.3/28.0° for AOD, TISA, and TIA, respectively.17
The spectral-domain OCT
The basic working principle of spectral-domain OCT is similar to time-domain OCT.19, 20 Both systems measure the echo time delay of backscattered light signals via an interferometer. In time-domain OCT, the depth information of the retina is collected as a function of time by moving the reference mirror. The reference mirror in spectral domain OCT, in contrast, is stationary. The light spectrum from the interferometer is detected by a spectrometer. The interference spectrum data is then fourier transformed to generate axial measurements. For this reason, spectral-domain OCT has a much faster scan speed (at least 20 000 A-scans per s) compared with time-domain OCT.
The use of spectral-domain OCT for anterior segment imaging was first described by Radhakrishnan et al in 2001.19 Using a semiconductor optical amplifier light source at a wavelength of 1310 nm, they imaged the anterior segment at a rate of 4–16 frames per s with an axial resolution of 8 μm. Except for the ciliary body, the angle configuration and the scleral spur were clearly visible. Although at least eight commercially available spectral-domain OCT models have been introduced for imaging the optic disc and the macula since 2006, only a few are equipped with additional lens system for anterior segment imaging. By attaching the cornea-anterior module (CAM), the RTVue FD-OCT (Optovue, Fremont, CA, USA) can take an image with dimensions of 6 × 2 mm (CAM-L) or 2 × 2 mm (CAM-S) at the angle (Figure 3a). CAM-L has a lower magnification but a wider field of view compared with CAM-S. The Cirrus HD-OCT (Carl Zeiss Meditec) also allows anterior segment imaging with the built-in 60-diopter aspheric lens. The ‘anterior segment five-line raster’ is the preferred scan protocol for the angle. The lines are 3 mm in width and covering 1 mm in depth by default (Figure 3b). Using a superluminescent diode laser wavelength of 840 nm in both Cirrus HD-OCT and RTvue FD-OCT, the scleral spur may not be clearly visible although it is possible to identify the Schwalbe's line in most cases (Figure 3a and b). Wong et al12 showed that the Cirrus HD-OCT was capable of detecting the scleral spur in 78.9% and the Schawbles’ line in 93.3% of quadrants in 45 individuals (a total of 90 nasal and temporal quadrants) recruited from a glaucoma clinic. As the current software of the RTVue FD-OCT (ver. 4.0) and Cirrus HD-OCT (ver. 5.1) does not adjust for refraction at the air-cornea and cornea-aqueous interfaces (dewarping), imaging should be performed in a direction perpendicular to the limbus to minimize the effect of image distortion. Wylêgała et al21 compared RTVue FD-OCT and Visante OCT for measurement of TIA and AOD in 30 normal volunteers, and did not find any significant differences between the instruments. The measurement repeatability and reproducibility of RTVue FD-OCT and Cirrus HD-OCT has not been reported. With a poorer visibility of the scleral spur, the measurement reliability for AOD, TIA, TISA, and ARA might be inferior compared with Visante OCT and SL-OCT. New parameters measured with reference to the Schawbles’ line may be more useful to quantify the angle dimensions with these devices.22
The swept-source OCT
The swept-source OCT is a form of fourier-domain OCT. Instead of using a spectrometer as in spectral-domain OCT, swept-source OCT uses a monochromatic tunable fast scanning laser source and a photodetector to detect wavelength-resolved interference signal.23, 24 The CASIA OCT (Tomey, Nagoya, Japan) is a commercially available swept-source OCT designed specifically for anterior segment imaging. The wavelength of the swept-source laser is 1310 nm. The scan dimensions are up to 16 mm (width) × 16 mm (length) × 6 mm (depth). With a scan speed of 30 000 A-scans per s, it is feasible to collect a series of 64 radial scans across the whole anterior chamber in 1.2 s. With reconstruction of individual image frames, a three-dimensional display of the iris and the anterior chamber angle can be generated (Figure 4).
An advantage of the CASIA OCT is the ability to visualize both the scleral spur and the Schwalbe's line in high-resolution scan mode (Figure 3c). These landmarks represent the boundaries of the trabecular meshwork. Being able to detect the location and measure the dimension of trabecular meshwork may improve the precision of angle measurements and detection of angle closure. The current definitions of angle parameters are made with an assumption that the trabecular meshwork can be found at a distance approximately 500–750 μm away from the scleral spur. This assumption has not been validated. The measurement of trabecular meshwork distance (the distance between the scleral spur and the Schwalbe's line) in relation to the peripheral iris might provide a more reliable approach to quantify the angle.
The applications of OCT for investigation of primary angle closure
OCT imaging has improved the diagnostic performance to detect angle closure. Defining a closed anterior chamber angle as the presence of any contact between the iris and angle wall anterior to the scleral spur, Sakata et al25 showed the Visante OCT detected a closed angle in at least one-quadrant in 59% of the eyes but only 33% by gonioscopy in a community clinic. In all, 71% of cases with closed angles on OCT but open angles by gonioscopy had a short irido-angle contact. The higher proportion of quadrants identified as closed angles on OCT imaging is likely related to the better visualization of the peripheral iris in contact with the trabecular meshwork. Half of the cases with open angles on OCT but closed angles by gonioscopy were found to have a steep iris profile. A false impression of angle closure may result in these eyes by gonioscopy and tilting of the goniolens often is needed to maximize the view of the angles.
OCT imaging can provide mechanistic insights into the pathophysiology of angle closure. The change from a forward bowing to a flattening configuration of the iris after laser iridotomy in eyes with angle closure demonstrates the relief of relative pupillary block and elimination of pressure gradient between the anterior and posterior chambers.3, 4, 5, 6 Widening of the angles has been consistently reported after lens extraction signifying the role of aging lens in contributing to angle closure and supporting lens extraction as a treatment option in management of primary angle closure glaucoma.26, 27, 28, 29
The measurement of the scleral spur to scleral spur distance with OCT, or the anterior chamber width, has been recently shown to be a risk factor of angle closure.30 Leung et al31 compared the anterior chamber width, anterior chamber depth, iris thickness, and angle width measured with an anterior segment OCT between Chinese and Caucasian eyes. In agreement with the finding from an epidemiology study,32 the axial length was not significantly different between the two ethnic groups. More important, the anterior chamber width was found to be shorter in Chinese than in Caucasian eyes even after adjustment of the anterior chamber depth. In other words, the iris-lens diaphragm is more anteriorly located in Chinese. This finding might explain in part the ethnic differences in development of primary angle closure and angle closure glaucoma.
In addition to the anterior chamber width, measurement of the iris has also shown to be important in determining the risk of angle closure.33, 34, 35, 36, 37 Aptel and Denis34 estimated the iris volume by capturing four cross-sectional images of the anterior segment at 45°-intervals. They showed that iris volume increased from ∼45 mm3 to 50 mm3 after pharmacologic mydriasis in the fellow non-attacked eyes of patients with history of acute primary angle closure. In contrast, in normal eyes with open-angles, iris volume decreased from ∼44 mm3 to 38 mm3 after pupil dilation. It has been proposed that differences in iris connective tissue and permeability of the iris stroma to aqueous may account for the differences in volume change in eyes with closed angles and open angles.38 The expansion in iris with dilation may block aqueous drainage at the angle and predispose to angle closure. Wang et al36 measured iris curvature, iris area, and iris thickness with the Visante OCT and showed that these parameters were independently associated with narrow angles. Cheung et al studied the dynamic changes of iris configuration with real-time video capture using the Visante OCT. They found the iris in eyes with narrow or closed angles consistently remained in an anteriorly convex configuration in both light and dark conditions and that the iris curvature is an important determinant of the angle width. With the advent of the spectral-domain and swept-source OCT imaging systems, iris volume and iris configuration can be quantified in more details. This information would be valuable in studying iris dynamics in relation to development of primary angle closure.
Summary
Ultrahigh speed 1050 nm swept-source fourier-domain OCT for anterior segment imaging is under development and imaging at a speed of 100 000 to 400 000 axial scans per s has been recently demonstrated.39 With the development of high-resolution and high-speed OCT imaging systems, angle structures including the scleral spur, Schwalbe's line and Schlemm's canal can be examined. The iris profiles and the angle configurations can be visualized three dimensionally and evaluated for 360°. It is conceivable that OCT imaging of the anterior segment could improve detection of angle closure and provide mechanistic insights into the pathophysiology of acute primary angle closure and angle closure glaucoma.
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Acknowledgements
CL has received research support from Carl Zeiss Meditec, Optovue, and Tomey, and honorarium from Carl Zeiss Meditec for conference presentation. RW is a consultant to Carl Zeiss Meditec. RW has received research support from Carl Zeiss Meditec and Optovue.
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Leung, CS., Weinreb, R. Anterior chamber angle imaging with optical coherence tomography. Eye 25, 261–267 (2011). https://doi.org/10.1038/eye.2010.201
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DOI: https://doi.org/10.1038/eye.2010.201
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