1.

Introduction

Glaucoma is an irreversible progressive optic neuropathy associated with loss of retinal ganglion cells (RGCs).¹ It is known as “the silent thief of sight,” since there are usually no symptoms until vision impairment has occurred and becomes irreversible. Typically by the time functional changes are detected, 30% of RGCs have already been lost.^2,3 As early treatment can significantly reduce the risk of glaucoma, preclinical detection prior to the onset of functional visual field defects holds the key for prevention of vision loss.^4,5

Optical coherence tomography (OCT) has become a standard-of-care test for glaucoma management and plays an important role in disease diagnosis by identifying thinning in the peripapillary retinal nerve fiber layer (RNFL).^6–8 While OCT imaging is capable of detecting thickness change prior to development of measurable peripheral field loss, RNFL thinning alone is not sensitive enough to differentiate early glaucoma from the high-risk glaucoma suspect who may benefit from earlier treatment.⁹ Recent advances in optical coherence tomography angiography (OCTA) have directed attention to measuring capillary flow index and capillary density in the peripapillary region,^10–15 but the sensitivity of these markers for early detection of glaucoma is still under investigation. Meanwhile, the development of visible light OCT (vis-OCT) has drawn interest in the ophthalmic applications for several distinct advantages recently.^16–18 First, due to the distinct absorption spectra of oxy- and deoxyhemoglobin in the visible light range, this technology allows functional measurement of both hemoglobin oxygen saturation (${\mathrm{sO}}_2$) and (in combination with blood flow measurements) the inner retinal oxygen metabolic rate (${\mathrm{MRO}}_2$).¹⁹ Second, by comparing the reflected signals between visible light and near-infrared (NIR) OCT images, the light scattering spectroscopic (LSS) contrast can detect ultrastructural changes in the retina beyond the resolution limit of current commercial imaging devices.^20–22 This LSS contrast can be quantified by a novel optical marker, called the VN ratio, that normalizes the visible light OCT images with NIR ones. Previous data suggest that pathologic changes in the RGC cytoskeleton occur at a length scale $<300\mathrm{nm}$, and the use of LSS contrast or VN ratio can allow us to optically detect structural alteration prior to RNFL thinning.^23,24 Lastly, vis-OCT can achieve 1 to $2\mu \mathrm{m}$ axial resolution,^17,25 offering the potential to detect subtle RNFL thickness changes and refine current measurement capabilities.

To fully utilize the advantages of vis-OCT, we have developed and implemented a fiber-based visible and near-infrared OCT (vnOCT) for simultaneous dual-band retinal imaging.²¹ The combination of the two bands allows multimetric measurement of the abovementioned spectroscopic markers, including VN ratio in the RNFL-RGC complex and ${\mathrm{sO}}_2$ in the inner retinal circulation. The purpose of this study is to apply vnOCT in a dexamethasone-induced ocular hypertension mouse model of early glaucoma and to explore whether the spectroscopic markers can detect changes of retinal ultrastructure or circulation. We compared intraocular pressure (IOP) and RGC loss in dexamethasone-treated and control mice and longitudinally measured ${\mathrm{sO}}_2$, retinal blood flow, RNFL thickness, and VN ratio. The alterations and relation of these metrics may provide valuable insight into the pressure-related pathophysiology of glaucoma and lead to the development of optical markers that can translate into early clinical detection of glaucoma.

2.

Methods

All animal procedures were approved by the Institutional Animal Care and Use Committee at Boston Medical Center and conformed to the guidelines on the use of animals from the NIH and the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research.

2.1.

Visible and Near-Infrared Optical Coherence Tomography Setup

The dual-band OCT setup used in this study is modified from our previous publication,²¹ as shown in Fig. 1. Briefly, a supercontinuum laser provided both visible light and NIR illumination, from 540 to 600 nm and 800 to 875 nm, respectively. The visible light was separated from the NIR by a dichroic mirror (DMLP650R, Thorlabs), dispersed by a pair of prisms, and filtered by a slit aperture. The filtered light was reflected by a mirror and coupled in an optical fiber. The NIR range was also separated by another dichroic mirror (DMLP900R, Thorlabs), filtered by two edge filters (DMLP805, Thorlabs and 19354, Edmund Optics), and coupled into an optical fiber. The two bands were combined by a custom-made wavelength division multiplexer (WDM) and directed into a 90/10 optical fiber coupler (TW670R2A2, Thorlabs). The returning light was separated by another WDM for the visible and NIR channels and recorded by two separate spectrometers equipped with 2048 pixel line scan cameras (Basler, splk2048-140k) and running at a 50-kHz A-line rate. Because both bands propagate within the same optical fiber, they shared the same sample arm and reference arm. The sample arm consisted of a collimator ($f=6\mathrm{mm}$), a two axis galvanometer scanner (GVSM002, Thorlabs), and a 3:1 telescope ($f=75\mathrm{mm}$ and $f=25\mathrm{mm}$) to relay light to the pupil. The reference arm consisted of a collimator ($f=10\mathrm{mm}$), several dispersion control BK-7 plates, a variable neutral density filter, and a mirror to reflect the light. The beam size on the pupil is about 0.2 mm in diameter. The incident optical power on the mouse pupil is 0.3 and 0.8 mW, in the visible light and NIR bands, respectively. The exposure time of the camera was $17\mu \mathrm{s}$ for an A-line rate of 50 kHz. The field of view was $1.2\times 1.2{\mathrm{mm}}^2$. The axial and lateral resolutions were estimated to be 2.7 and $6.7\mu \mathrm{m}$ for the visible band, 5.6 and $10.2\mu \mathrm{m}$ for NIR band, respectively. The system acquires visible and NIR OCT images simultaneously.

Fig. 1

Schematic of the vnOCT system setup. Two WDM and a fiber coupler merge and split the visible and NIR channels. The same sample and reference arms are shared by two channels, which are collected by separate spectrometers. SC, supercontinuum source; DM, dichroic mirror; BD, beam dumper; PBS, polarization beam splitter; DP, dispersive prism; M, mirror; EFs, two edge filters; OBJ, objective lens; PC, polarization controller; CL, collimating lens; GM, galvanometer mirror; L, lens; ND, neutral density filter; DC, dispersion compensation plates; VIS SPE, visible band spectrometer; NIR SPE, near-infrared band spectrometer.

2.3.

Blood Hemoglobin Saturation (${\mathrm{sO}}_2$)

We used the previously published method for calculating ${\mathrm{sO}}_2$ from retinal arteries and veins,^16,19 as shown in Fig. 2(c). The 3-D images from the visible light channel were used. A short-time Fourier transform with a sweeping Gaussian window in $k$ spectral domain ($k=2\pi /\lambda$) was performed to generate wavelength-dependent vis-OCT images. The full width at half maximum of the $k$-domain Gaussian window was $k_w=0.32{\mu \mathrm{m}}^{-1}$. We used 11 windows to generate four-dimensional data ($x,y,z,\lambda$). The retinal surface was identified by setting an intensity threshold. To reduce the dimension, individual vessels were first segmented from the en face projection, and all the A-lines within each vessel were lined-up to a 2-D B-scan. Then each A-line was shifted in reference to the retinal surface. The signal from the bottom wall of each individual vessel was averaged, and the same process was iterated for each spectral window to generate a spectrum for each vessel. Lastly, the following analytical model was used to fit the spectrum to calculate ${\mathrm{sO}}_2$ from 545 to 580 nm:

Eq. (1)

$$I^2(\lambda )=I_0^2(\lambda )R_{0}r(\lambda )\exp [-2d{\mu }_{{\mathrm{HbO}}_2}(\lambda )\times {\mathrm{sO}}_2-2d{\mu }_{\mathrm{Hb}}(\lambda )\times (1-{\mathrm{sO}}_2)],$$

where $I_0(\lambda )$ is the incident spectrum on the retina; $R_0$ is the reference arm reflectance; $d$ (mm) is the vessel diameter; and $r(\lambda )$ (dimensionless) is the reflectance at the vessel wall, whose scattering spectrum is modeled as a power law under the first-order Born approximation $r(\lambda )=A{\lambda }^{-}$, where A (dimensionless) is a constant.²⁶ The subscripts Hb and ${\mathrm{HbO}}_2$ denote the contribution from deoxygenated and oxygenated blood, respectively. The optical attenuation coefficient $\mu$ (${\mathrm{mm}}^{-1}$) combines the absorption (${\mu }_{\mathrm{a}}$) and scattering coefficients (${\mu }_{\mathrm{s}}$) of the whole blood, which are both wavelength- and oxygenation-dependent:

Eq. (2)

$$\mu (\lambda )={\mu }_{\mathrm{a}}(\lambda )+0.2{\mu }_{\mathrm{s}}(\lambda ).$$

Fig. 2

Multimetric measurements by vnOCT. (a), (b) En face projection of mouse retina in the visible and NIR channels, respectively. Two concentric circles represent the dual-circle scanning pattern. (c) Method for ${\mathrm{sO}}_2$ calculation by vessel segmentation and subsequent spectroscopic analysis. The vessel location was first manually segmented, and short-time Fourier transform was performed to obtain 4-D data ($x,y,z,\lambda$). Finally, the spectra from the bottom vessel wall were averaged and fitted by Eq. (1). (d) The schematic of blood flow measurements. The difference of the phase contrast from the inner and outer circles was used to calculate Doppler angle and blood velocity. (e) Illustration of RNFL thickness and RNFL-RRC VN ratio calculation. The circular B-scan image in visible light OCT was used to calculate RNFL thickness, as shown in yellow arrows. The intensity ratio between the visible and NIR channels was defined as VN ratio.

The values of ${\mu }_{\mathrm{a}}$ and ${\mu }_{\mathrm{s}}$ are provided by the literature.²⁷ A least-square linear regression to the logarithmic spectra returned the value of ${\mathrm{sO}}_2$. We averaged ${\mathrm{sO}}_2$ from all the arteries and veins, respectively, for each retina.

2.10.

Statistical Analysis

Two sample Student’s $T$-test was used in Figs. 3 and 4. The Pearson’s linear regression was used to test the correlation among IOP, VN ratio, and ${\mathrm{sO}}_2$ in Fig. 5.

Fig. 3

Characterization of the dexamethasone-induced ocular hypertension mouse model. (a) The timeline of measurements over the span of 7 weeks. (b) Weekly measurements of IOP by a tonometer. (c) Representative confocal fluorescence microscopic images of anti-Brn3a immunostaining for RGCs, in the saline and dexamethasone groups. (d) Comparison of the RGC density between saline ($n=8$) and dexamethasone groups ($n=8$). $*p<0.05$, $**p<0.01$, $***p<0.001$. Error bar = SEM.

Fig. 4

Longitudinal measurements by vnOCT at weeks 0, 4, and 7 for (a) RNFL thickness ($\mu \mathrm{m}$), (b) blood flow ($\mu \mathrm{L}/\min$), (c) VN ratio, (d) arterial ${\mathrm{sO}}_2$, (e) venous ${\mathrm{sO}}_2$, and (f) arteriovenous(A-V) ${\mathrm{sO}}_2$ difference. $*P<0.05$; $**P<0.01$; $****P<0.0001$. Error bar = SEM.

Fig. 5

Correlation among vnOCT markers, IOP and RGC density in the dexamethasone-treated group. (a), (b) The correlation between VN ratio and IOP in each eye in the dexamethasone group at week 0 and weeks 4 and 7. (c), (d) The correlation between A-V ${\mathrm{sO}}_2$ difference and IOP in each eye in the dexamethasone group at week 0 and weeks 4 and 7. (e)–(g) The correlation between VN ratio, A-V ${\mathrm{sO}}_2$ difference, IOP and RGC density in each eye in the dexamethasone group at terminal week 7.

3.

Results

The study design is shown in Fig. 3(a). IOP measurements were performed weekly to confirm the induced ocular hypertension. The vnOCT imaging was performed longitudinally at the baseline week 0, week 4, and week 7. The study was terminated at 7 weeks, and the effectiveness of the model was further verified by measuring RGC loss via immunostaining and cell counting. The study started with 12 animals, six in the dexamethasone group and six in the control group. Four animals from each group reached the terminal stage at week 7 (Table 1).

Table 1

Summary of IOP (mmHg) for individual retinas.

The animal model was first validated by measuring IOP and then RGC counting. Baseline IOP was noted to be $14.2\pm 1.7$ and $15.3\pm 1.2$ for both the control and dexamethasone group, respectively, and this was not statistically different. The IOP in the dexamethasone group showed a statistically significant increase as compared to the control group by week 2 [$p<0.05$, Fig. 3(b)]. The characteristics of the IOP change are consistent with multiple previous publications using this animal model.^36–38 The RGC density (cells per ${10}^2{\mu \mathrm{m}}^2$) as measured by confocal fluorescence microscopic images at week 7 [Figs. 3(c) and 3(d)] was significantly decreased in the dexamethasone group compared to the control group [$p=0.0002$, Fig. 3(e)], confirming the RGC loss.

The results of longitudinal multimetric measurements by vnOCT are summarized in Fig. 4 and Table 2. The RNFL thickness was similar at baseline between the two groups and did not change significantly from baseline to week 4 or 7 for either group, or comparatively [Fig. 4(a)]. Blood flow measurements were similar at baseline and showed only a moderate decrease when comparing the dexamethasone to control group at weeks 4 ($p=0.36$) and 7 ($p=0.65$) [Fig. 4(b)]. Baseline RNFL-RGC VN ratio measurements were similar between the two groups, but decreased progressively at week 4 ($p=0.0048$) and 7 ($p=0.00009$) in the dexamethasone group compared to the control group [Fig. 4(c)]. This change is consistent with the previous reported spectroscopic change, which was attributed to the ultrastructural cytoskeleton loss in RGCs.²⁴

The retinal arterial and venous ${\mathrm{sO}}_2$ were similar at baseline between the two groups. The arterial ${\mathrm{sO}}_2$ did not show any statistically significant change temporally or comparatively between the groups throughout the study. The venous ${\mathrm{sO}}_2$ did show a progressive drop in the dexamethasone group compared to the control, which was statistically significant at week 7 [$p=0.01$, Fig. 4(e)]. As a result, the A-V ${\mathrm{sO}}_2$ also showed a progressive increase at week 4 ($p=0.039$) and week 7 ($p=0.016$), indicating a higher oxygen extraction efficiency from the inner retinal circulation in the dexamethasone versus control group [Fig. 4(f)].

Table 2

Summary for longitudinal measurements by vnOCT.

Since the vnOCT measurements showed that VN ratio and A-V ${\mathrm{sO}}_2$ were significantly altered in dexamethasone group, we next examined the correlation of these two markers to IOP and RGC loss. We first compared VN ratio, and A-V ${\mathrm{sO}}_2$ with IOP at weeks 0 and week 4 and 7 in dexamethasone-treated ocular hypertensive eyes [Figs. 5(a)–5(d)] and found only weak correlation by Pearson’s test. We next compared RGC density measurement with the terminal measurement of VN ratio, A-V ${\mathrm{sO}}_2$ difference, and IOP at week 7 [Figs. 5(e)–5(g)]. Although the sample number is small, there appears to be moderate correlation between VN ratio, A-V ${\mathrm{sO}}_2$, IOP, and RGC loss. This analysis suggests that VN ratio and A-V ${\mathrm{sO}}_2$ may effectively serve as markers for RGC damage, potentially independent of IOP.

4.

Discussion

In this study, we demonstrated that spectroscopic markers (VN ratio and A-V ${\mathrm{sO}}_2$) enabled by vnOCT have the potential to detect VN ratio changes in the RNFL-RGC and alterations in blood hemoglobin ${\mathrm{sO}}_2$ within the inner retinal circulation associated with ocular hypertension in a mouse model. These findings suggest that a decreased VN ratio and an increased A-V ${\mathrm{sO}}_2$ difference may represent early changes in the development of glaucoma.

One key measurement enabled by vnOCT is RNFL-RGC VN ratio, which quantifies the spectral contrast between visible and NIR channels. The image intensities of visible and/or NIR band can be variable across retinas and within retina, affected by the transmission from anterior part of the eye, angle of the laser passing through the pupil, and the eye quality (dry or moist, eye condition etc.). To control those experimental variables, we have used the circulating whole blood as an in situ spectral reference to calibrate systemic variations and used the mean VN ratio to represent the whole retina. The VN ratio calculated from different thickness from the surface of the retina is shown as Fig. 6. It shows that the calculation tends to stabilize after 25 to $30\mu \mathrm{m}$ thickness, and the separation between ocular hypertensive and control eyes was still significant. Therefore, we used $30\mu \mathrm{m}$ for all our calculation, for consistency. Although the superficial $30\mu \mathrm{m}$ tissue also includes some signals from RGCs, the depth selection was a balance for the measurement robustness. We also took total blood flow, mean ${\mathrm{sO}}_2$ over arterials and venules, and mean RNFL thickness to represent each retina in this study.

Fig. 6

VN ratio calculated from varying thickness from the retinal surface at week 7. Solid and blank symbols labeled the eyes in control and Dex groups, respectively.

The dexamethasone mouse is a well-established model of steroid-induced ocular hypertension and glaucoma.^36–38 Consistent with previous reports, our mice developed significantly increased IOP within 2 weeks of starting topical dexamethasone drops with subsequent progression to RGC loss. The mechanism by which steroids cause ocular hypertension remains to be fully elucidated but decreased outflow facility is considered the main contributing factor. Phulke et al.³⁹ have nicely outlined the leading molecular pathways to reduced outflow facility including accumulation of glycosaminoglycans, laminin, elastin, and fibronectin in the trabecular meshwork (TM), increased TM cell nuclear size and DNA content, and decreased prostaglandin synthesis.^39–43 Steroids may also upregulate myocylin gene (MYOC/GLC1A) expression, accumulation of which is an initial step in the development of glaucoma.^44,45 A number of other genes are thought to contribute as well, though their significance is still being evaluated.^46–48 The resulting elevated IOP is transmitted posteriorly inducing a cascade of events that ultimately cause RGC axonal damage followed by RGC loss, mimicking the major pathologic events of primary open angle glaucoma.

While our study found an early elevation in IOP and resulting RGC loss, it did not result in significant change to the RNFL thickness within the first 7 weeks in our study. This finding/result corroborates with other preclinical studies having shown that RGC loss precedes RNFL thickness change following acute optic nerve injury.^49,50 The VN ratio, however, progressively decreased over this time period, suggesting that ultrastructural changes may precede RNFL loss in early glaucoma. As the VN ratio is derived from the superficial $30\mu \mathrm{m}$ of RNFL-RGC around the ONH, it primarily represents signal from RGC axons, in which microtubules contribute a significant portion of the measured reflectance.⁵¹ Therefore, the decreased VN ratio may reflect ocular hypertension-induced structural alterations in the RGC cytoskeletons.^52,53 Indeed, previous ex vivo studies have established that the cytoskeletal alterations in RNFL axons is an early event of RGC damage, resulting a “flatter” reflectance spectrum from RNFL, detectable prior to RNFL thinning.²⁴ This altered reflectance spectrum corresponds to our findings of a decreased VN ratio, further supporting our hypothesis that the decreased VN ratio may be a sensitive ultrastructural optical marker for early detection of RGC damage. One discrepancy between our study and the previous study is that ex vivo retinas have VN ratio larger than 1 while we found VN ratio slightly less than 1 from in vivo retinas when we compared visible and NIR bands centered at 560 and 820 nm. The study by Yi et al.⁵⁴ used fixed ex vivo retinas and only investigated changes in visible light range by confocal reflectance microscopy. The study by Huang et al.²⁴ used different device and normalization methods for spectral characterization and used a different ex vivo preparation for retina culturing. Those differences are all likely to cause the discrepancy.

Alterations in the retinal circulation are considered important events in glaucoma development.⁵⁵ Lower ocular perfusion pressure and low systolic and diastolic blood pressure are known to be major risk factors for glaucoma.⁵⁶ Numerous studies have consistently shown the reduced blood flow in glaucomatous eyes.^14,57–59 Recent OCTA studies have shown that the peripapillary capillary vasculature density and capillary flow index are compromised in advanced glaucomatous eyes,^10–15 suggesting microvascular perfusion around the ONH is an important factor in glaucoma’s pathogenesis. As retinal function relies on oxygen metabolism, changes in blood ${\mathrm{sO}}_2$ represent an attractive potential indicator of functional impairment. In our study, blood flow shows only a moderate decrease in the dexamethasone group compared to control group at weeks 4 and 7. The increased arteriovenous ${\mathrm{sO}}_2$ difference (A-V ${\mathrm{sO}}_2$), driven by decreased venous ${\mathrm{sO}}_2$, is more significant, indicating more oxygen extraction from the retinal circulation. Even with the mild decrease in blood flow, overall oxygen consumption from the retinal circulation increases, suggesting a state of oxygen hypermetabolism. This finding is in contrast to later stages of glaucoma when A-V ${\mathrm{sO}}_2$ is found to be decreased due to advanced cell loss and decreased oxygen consumption.⁶⁰ Our suggestion of a dynamic change in oxygen metabolism associated with glaucoma progression is consistent with previous studies of a diabetic retinopathy mouse model, in which early oxygen hypermetabolism eventually gives way to a cell death-mediated decrease in oxygen consumption.⁶¹ The underlying biology of the early hypermetabolism is not clear at this moment and requires further investigation. Nevertheless, our data herein suggest that in early stage glaucoma, global alterations of ${\mathrm{sO}}_2$ might be another sensitive marker for early glaucoma.

The major limitation of this study is the limited number of data points by week 7, when only four animals and five eyes per group producing good quality images and vnOCT readings, thereby limiting the statistical power in Figs. 5(c) and 5(d). Several animals expired during the study and loss of corneal clarity in some eyes prevented reliable retinal imaging. It is reassuring, however, that measured changes of RNFL VN ratio and AV-${\mathrm{sO}}_2$ difference already reached statistical significance with a higher number of data points by week 4.

5.

Conclusion

In summary, we demonstrate that vnOCT can detect spectroscopic changes in RNFL-RGC, in addition to changes in the oxygen levels in the retinal circulation in a dexamethasone-induced ocular hypertension mouse model. The changes were identifiable even within the short-time frame of this study, indicating that pressure elevations can result in retinal changes prior to measurable alteration of RNFL thickness. These findings pave the way for future studies in mice and humans to gain further insight as to how changes progress, if they are reversible, and how they may respond to treatment.