This cross-sectional study reviewed the medical records of patients who visited the Neuro-ophthalmology and Glaucoma Department of Samsung Medical Center (Seoul, South Korea) between July 2018 and February 2023. This study followed all guidelines for experimental investigation in human subjects, was approved by the Samsung Medical Center Institutional Review Board, and adhered to the tenets of the Declaration of Helsinki. 

We included patients ≥ 20 years of age with CON in chiasmal compression and those with NTG. The clinical diagnosis of chiasmal compression was based on preoperative VF defects and/or decreased visual acuity and magnetic resonance imaging (MRI) evidence of mass compression of the optic chiasm. All of the patients underwent transsphenoidal resection. We only included patients with CON who underwent OCTA at the chronic stage, over 6 months after their surgery. The purpose of this study was to compare the different relationships of VD and RNFL thinning between CON and NTG, rather than to identify a method for early differential diagnosis. Thus, we specifically included eyes with a disease onset > 6 months, as progressive thinning of the GCIPL has been reported for up to 1 year in patients with CON.⁸ 

NTG was defined as an open angle on gonioscopy, signs of glaucomatous optic nerve damage (i.e., neuroretinal rim notching, thinning, or localized RNFL defect), a glaucomatous VF defect, and untreated baseline intraocular pressure (IOP) ≤ 21 mmHg. A glaucomatous VF defect was defined as a defect conforming to one or more of the following criteria: (1) results outside normal limits on a glaucoma hemifield test; (2) at least three adjacent abnormal points with a P < 0.05 probability of being normal and at least one of these being abnormal with a P < 0.01 probability by pattern deviation; or (3) a pattern standard deviation of P < 0.05, as confirmed on two consecutive reliable tests. 

We particularly selected patients with a similar mean degree of macular GCIPL loss, determined by the area of the abnormal macular GCIPL thinning in thickness maps of < 75 µm. For patients with CON, we included eyes with vertical GCIPL losses of ≥50% of the area. For patients with NTG, we included eyes with horizontal GCIPL losses of complete or near-complete 50% of the area due to the characteristic fovea-sparing of glaucomatous RNFL damage. These criteria were chosen over VF or pRNFL because of the subjectivity of VF, considerable interindividual variability of VF and pRNFL, and a closer association with central VF damage of clinical importance than with peripapillary RNFL loss. 

The exclusion criteria were as follows: (1) patients with coexistent glaucoma; (2) patients with any other ocular (retinal diseases and optic neuropathies other than glaucoma or chiasmal compression), neurological, or systemic diseases, or previous retinal surgery that might affect OCT or OCTA images; and (3) patients with poor-quality OCT or OCTA images. 

All participants underwent visual acuity assessments, refraction tests, slit-lamp biomicroscopy, tonometry, dilated stereoscopic examinations of the optic disc, color fundus photography (TRC-50DX mydriatic retinal camera; Topcon Healthcare, Oakland, NJ, USA), spectral-domain OCT with the CIRRUS HD-OCT (Carl Zeiss Meditec, Jena, Germany), OCTA (DRI OCT Triton Plus; Topcon, Tokyo, Japan), and standard automated perimetry (Humphrey Field Analyzer 640, with 30-2 or 24-2 Swedish interactive threshold algorithm; Carl-Zeiss Meditec, Dublin, CA, USA). 

The peripapillary and macular areas were imaged using a commercially available swept-source OCTA device (Topcon DRI OCT Triton Plus) with a central wavelength of 1050 nm, an acquisition speed of 100,000 A-scans per second, and axial and transverse resolutions of 7 µm and 20 µm, respectively, in tissues. En face projections of volumetric scans allowed visualization of structural and vascular details within the segmented layers. An active eye tracker that follows eye movements detected blinking and adjusted the scan position accordingly, thereby reducing motion artifacts during the acquisition of OCTA images. OCTA images were excluded if they had (1) low image quality score of <40, or (2) image artifacts such as decentration, segmentation, motion, blinking, and shadows.⁹ Artifacts were defined according to previous reports^9,10: Segmentation errors were defined as errors in the segmentation of the retinal layers leading to a deviation of the slab; motion artifacts referred to vertical or horizontal white lines, interruption, displacement, or doubling of vessels; blink artifacts were defined as a signal void black band composed of multiple adjacent B-scans on the en face OCTA due to closure of the eye during image capture; and shadow artifacts referred to localized, decreased intensity of the retinal layers. 

Each patient underwent two imaging sessions consisting of a peripapillary scan (4.5 mm  ×  4.5 mm) centered on the optic disc and a 3.0 mm  ×  3.0 mm perifoveal scan centered on the macula (both resolution of 320 × 320 pixels). Peripapillary VD was calculated from en face OCTA images of the radial peripapillary capillary (RPC) layer generated by automated layer segmentation from the internal limiting membrane (ILM) to the posterior boundary of the RNFL. The software automatically fitted a 3-mm Early Treatment Diabetic Retinopathy Study (ETDRS) circle at the disk center and generated the vessel density for each sector. The location of the center of the optic disk was manually corrected when necessary. Macular VD was calculated from en face OCTA images of the superficial retinal capillary plexus extending from 3 µm below the ILM to 15 µm below the IPL. The same 3-mm ETDRS circle fitted at the foveal center automatically generated the VD. The ETDRS circle provides five VD areas (central, nasal, temporal, superior, and inferior). The RPC and superficial retinal capillary plexuses were automatically separated via layer segmentation using the OCT instrument software (IMAGEnet 6 V.1.14.8538). 

We also evaluated the clock-hour involvement in CON and NTG using OCT 12 clock-hour measurements. Clock-hour involvement was defined as a thickness measurement below the fifth percentile (yellow color), which corresponded to other examinations (fundus photo, OCT, VF, and OCTA) to ensure meaningful findings. 

We compared the structure–function and vasculature–function correlations by comparing the pRNFL thickness, peripapillary VD, and VF sensitivity. 

Both eyes were included if they satisfied the inclusion criteria. To compare the CON and NTG groups, we used a generalized estimation equation (GEE) to consider the possible relationship between both eyes of each patient. In the correlation analysis, the decibel (dB) values for the VF sensitivity were anti-logged to obtain the sensitivity on a linear scale (1/Lambert = 10^0.1×dB value).¹¹ Correlation was assessed by calculating Pearson's correlation coefficient. The Steiger test was performed to determine whether there was a significant difference in the correlation coefficients among the VD, pRNFL thickness, and VF mean deviation (MD) relationships. Univariate and multivariate logistic regression analyses were performed using the GEE. Factors with P < 0.2 in the univariate analysis were included in the multivariate analysis. Statistical significance was set at P < 0.05. All statistical analyses were performed using SPSS Statistics 23.0 (IBM, Chicago, IL, USA). 

The database included 184 patients with chiasmal compression who underwent surgery and were followed up for 6 months postoperatively, and 439 patients with NTG. We excluded CON patients with (1) no residual optic nerve damage (97 patients), or (2) mild damage that did not meet the inclusion criteria (33 patients). We excluded NTG patients with (1) mild RNFL defects that did not approach the horizontal raphe and fovea (287 patients), (2) substantial superotemporal defects (51 patients), or (3) far-advanced disease (36 patients). 

Initially, 54 patients with CON and 64 patients with NTG had comparable average areas of GCIPL thinning in the vertical and horizontal directions, respectively. Of the 152 eyes of the 123 patients, we excluded one eye with retinoschisis, eight eyes of seven patients with OCTA artifacts, six eyes of six patients with OCT artifacts, three eyes of three patients with media opacities, and four eyes of three patients with coexisting CON and glaucoma. Finally, we included 56 eyes from 40 patients with CON and 71 eyes from 60 patients with NTG. 

The baseline clinical characteristics are shown in Table 1. Age, refractive error, IOP at examination, average pRNFL thickness, average macular GCIPL thickness, and VF MD were all comparable between the two groups. Intracranial lesions in the CON group included pituitary adenoma (37 eyes in 27 patients), craniopharyngioma (12 eyes in eight patients), meningioma (four eyes in four patients), Rathke's cleft cyst (two eyes in one patient), and hypophysitis (two eyes in one patient). The interval between surgery and OCTA examination was 2.1 ± 1.4 years (range, 0.5–5.3). 

The CON group showed a significantly lower average peripapillary VD than the NTG group despite a similar GCIPL thickness, as well as average pRNFL thickness (Table 1). However, there were significant differences in the sectoral distribution of GCIPL thicknesses, as expected. 

The difference in average peripapillary VD was significant after adjusting for age, spherical equivalent, minimum GCIPL thickness, pRNFL thickness, and MD, as well as image quality scores (odds ratio [OR] = 0.649; 95% confidence interval [CI], 0.541–0.779; P < 0.001), as scan quality can significantly influence VD measurements on OCTA.^12–14 Peripapillary VD differed in all four sectors and was particularly different in the nasal and temporal sectors (Fig. 1). In contrast, the macular VD thickness did not differ between the two groups, as expected, except in the inferior sector. Minimum GCIPL thickness was lower in the NTG group than in the CON group. 

In addition, between CON eyes with clock-hour involvement ≤6 hours and NTG eyes (all ≤6 hours), the difference in average peripapillary VD was also significant after adjusting for age, spherical equivalent, minimum GCIPL thickness, pRNFL thickness, MD, and image quality score (OR = 0.611; 95% CI, 0.485–0.769; P < 0.001). Also, between eyes with clock-hour involvement ≤3 hours, the difference in average peripapillary VD was significant after adjusting for age, spherical equivalent, minimum GCIPL thickness, pRNFL thickness, MD, and image quality score (OR = 0.655; 95% CI, 0.487–0.881; P = 0.005). The results between eyes with clock-hour involvement >3 hours could not be calculated because of the small number of eyes. Different characteristics between CON and NTG subgroups by clock-hour involvement are shown in Supplementary Tables S1 and S2. None of the patients in our study had optic discs that were extremely large or small in size such that the ETDRS inner circle seemed inappropriate to provide reliable measurements for VD calculation. 

The correlation coefficients between OCT thickness, OCTA VD, and VF sensitivity are shown in Table 2. In the CON group, the average pRNFL and GCIPL thicknesses, average peripapillary VD, and average macular VD were significantly associated with VF MD. In the NTG group, only the average peripapillary and macular VDs were significantly associated with VF MD. The correlation between average macular GCIPL thickness and MD in the two groups was statistically significant (P = 0.012). In the CON group, the average pRNFL and GCIPL thicknesses were significantly associated with VF pattern standard deviation (PSD), whereas in the NTG group only the average pRNFL was significantly associated with VF PSD. Figure 2 shows representative cases. 

OCTA is a novel imaging technique that demonstrates microvascular changes in various optic neuropathies, such as glaucoma and ischemic and inflammatory optic neuropathies.^1,15–18 OCTA has shown a high correlation with OCT RNFL thickness measurements^19,20 and even better sensitivity.⁴ However, more information is needed to better understand OCTA in comparison to OCT, in terms of clinical utility regarding the mechanistic differences, applied in different diseases. 

In this cross-sectional study, we observed that VD measured in the peripapillary area was significantly lower in the CON group than in the NTG group, under similar average thickness measurements of peripapillary and macular areas. Our result is the first to compare VD between CON and NTG under a highly matched severity of damage by average thickness and highlights different characteristics between OCTA VD and OCT RNFL thickness measurements in the evaluation of optic neuropathies. 

Decreased VD has been reported in the peripapillary and macular areas in both CON and glaucoma, seperately.^{3,15,17,18,21} However, few studies have directly compared OCTA VD between eyes with CON and those with glaucoma. One study compared patients with CON and those with open-angle glaucoma who had similar average pRNFL thickness.² They reported that peripapillary retinal VD was significantly higher globally in CON (37.34% ± 3.38%) than in open-angle glaucoma (35.91% ± 3.27%) and normal controls (40.24% ± 2.62%),² a finding that was contrary to the findings of the present study on NTG. However, the previous study used en face slabs to measure the inner retinal layer, extending from the internal limiting membrane to 130 µm below it,² which differs from the technique used in our study. In addition, the average pRNFL thickness was similar in both groups (76.6 ± 19.8 µm in CON vs. 74.3 ± 10.2 µm in glaucoma); however, the VF MD was significantly worse in the CON group than in the glaucoma group (–7.40 ± 8.52 dB vs. –3.26 ± 2.42 dB), and it is unclear whether the severity of damage was highly matched between the two groups.² Lei et al.²² reported comparable peripapillary VD and lower superficial macular VD in the glaucoma group than in the CON group. However, they used different devices and different scan areas and included only 12 eyes of patients with CON and 15 eyes of patients with glaucoma. Moreover, if macula damage was controlled, the peripapillary VD would have been greater in the glaucoma group, as per our results. In addition, we studied NTG rather than open-angle glaucoma because differential diagnoses can be particularly challenging under normal IOP; no other study, to the best of our knowledge, has compared CON and NTG. As both of the two studies included patients with high-IOP primary open-angle glaucoma, the different patient group characteristics may also explain the different results from our study. 

In our study, the mean degree of macular GCIPL severity was highly controlled in the two groups. The CON group consisted of eyes with complete or near-complete vertical half-loss of the macular GCIPL by the area. The glaucoma group consisted of eyes with complete or near-complete horizontal half-loss of the macular GCIPL. In addition, only eyes with chronic CON were included in our study (on average, 2.1 years) because delayed RNFL thinning is possible up to 1 year postoperatively.⁸ This comparative design is new. As there was no reason in the design to diminish the validity of our results, we speculated that such design led to successful revealing of subtle difference in peripapillary VD indicative of the high sensitivity of OCTA. 

The potential utility of OCTA in addition to OCT arises from several possibilities. First, the floor effect in OCT is considered a candidate. It is caused by the thickness of remaining non-axonal components, such as vasculature and gliosis,²³ not allowing OCT thickness under 30 µm even with severe axonal degeneration.²⁴ In contrast, this floor effect is absent in OCTA measurements.²⁵ Second, topographic difference in detection sensitivity is also possible, regarding the physiologic thickness and structure of the RNFL. Specifically, the intergroup difference was most marked in the nasal sector in our study. The nasal sector is physiologically thinner than other sectors, a condition known to be difficult to detect noticeable thinning with OCT.^26,27 

In line with these characteristics, the marked dropout of the microvasculature was easily recognizable in the nasal sector (Fig. 2). In other words, the OCTA en face map provided an intuitive understanding of the different topographic patterns between CON and glaucoma (Fig. 3). 

Several other factors may also contribute to the different outcomes of OCT and OCTA. The VD was calculated as the percentage area of the pixels with binarized signals. In contrast, RNFL thickness measured by OCT is continuous and exhibits interindividual variations; therefore, VD may be less affected by interindividual variations in RNFL thickness, the reflectance of the RNFL, or optic disc tilt. This technique may enable an amplification effect focused on abnormality, which allows for sensitive detection of subtle changes that can be missed due to inherent technical limitations of OCT.^28–31 In addition, different “dynamic ranges” between neural structural changes and vessel density changes are also possible, as suggested by Shoji et al.¹⁷ Finally, the mechanism of VD loss may be diverse.^2,19 Reduced metabolic demand due to axonal atrophy is one possible mechanism.^20,32 However, differences between the pathogenesis of the focal VD dropout in the peripapillary choroid in cases of CON and glaucoma have been suggested.² Further investigations are warranted to better understand the detailed mechanisms. 

Nevertheless, several limitations must be acknowledged, particularly those stemming from the potential weaknesses inherent in the use of OCTA to calculate VD data. One limitation may be that the results from OCTA may only replicate those from OCT and may be more susceptible to bias. For example, topographical differences in RNFL thickness between the CON and NTG groups have already been demonstrated using OCT.³³ In addition, the long-term reproducibility of OCTA is less than that of OCT-measured thickness,³⁴ and OCTA may show image artifacts.^9,35,36 Moreover, technical issues exist in the calculation of VD, such as the exclusion of large vessels. Nevertheless, we believe that OCTA still has several merits for the following reasons. First, OCTA VD findings corroborated the pattern of differences observed between the CON and NTG in OCT while augmenting the differences more markedly, as shown in Figure 1. Second, the more pronounced presentation was not a transient artifact but rather a representation of true pathologic changes, as we not only analyzed the numerical data but also confirmed the correlation to fundus photographs, red-free photographs, VF, and OCT. Third, OCTA has the potential to provide valuable insights in locations where OCT may be limited. For example, the physiologically thin nasal sector, in which OCT could not detect a significant deviation from the normal population, showed decreased vascularity in many eyes in the CON group. Finally, it was recently shown that OCTA-measured macular and ONH vascular parameters have good long-term reproducibility.³⁴ Therefore, we consider that VD may facilitate easier recognition of pathological changes in certain circumstances and could be a helpful ancillary parameter for understanding the different characteristics of microvascular responses in different optic neuropathies through different devices. Similarly, Lee et al.²¹ have also postulated that the intraretinal vascular changes might be amplified, resulting in increased sensitivity of detection compared to that of pRNFL thickness. 

The main purpose of this study was not to identify an OCTA-based parameter for the differential diagnosis between CON and NTG but rather to understand the differential microvascular responses between the diseases and the varying outcomes reported between the devices. Therefore, the results of our study would not indicate that the VD parameter in OCTA may serve as a discriminator between CON and NTG. Instead, the results would illustrate the potential for sensitive detection of abnormalities in areas where conventional OCT may demonstrate limited performance. Nevertheless, considering the potential benefits of OCTA, we believe that further research aimed at differentiating between patients with early-stage CON, including those in the acute phase, and patients with glaucoma would also be immensely valuable. 

The peripapillary RNFL (ppRNFL) thickness tended to be thinner in the CON group than in the NTG group in our study. The statistically insignificant difference in average RNFL thickness, despite the significant difference in VD between the two diseases, may be attributed to the difference in the OCT device. Nevertheless, the current OCT ppRNFL thickness measurements successfully revealed topographic inter-group differences as well as highly indifferent macular GCIPL thicknesses, which are inevitably strongly correlated with ppRNFL thickness. Moreover, the VD difference between the groups was much more pronounced than those in the OCT measurements, which suggests that the disparity in OCT devices alone may not fully explain the observed results. Thus, we speculate that the milder difference in ppRNFL thickness compared to peripapillary vessel density (ppVD) may persist regardless of the OCT device used. 

During the examination, IOP was lower in the NTG group than in the CON group, which may be attributed to the use of IOP-lowering medications in patients with NTG. However, the effect of the IOP on VD outcomes is unclear. Although Chen et al.³⁷ reported that, in patients with ocular hypertension, a reduction in IOP by 6.5 mmHg could led to an 1.2% increase in peripapillary VD, the IOP difference was smaller (2.0 mmHg) in our study and the VD difference was larger (3.5%). The multivariate analysis also did not reveal a significant effect of IOP. 

In addition, our study supports the stronger correlation of IOP with VF^4,17,38–44 shown across different optic neuropathies. We suggest that differences in MD, PSD, and minimum GCIPL thickness indicate distinct patterns of RNFL damage between the CON and NTG groups. CON appears to involve a wider area of the nasal half of the RGC, whereas glaucoma is characterized by focal RGC loss exclusively around the macula. As expected, eyes with NTG demonstrated deeper VF loss, higher PSD, and lower minimum GCIPL thickness. Because the worst MD was in the NTG group than in the CON group, we speculated that the dramatic VF recovery following surgical decompression in the CON group could be related. 

We would like to address that the pattern of RNFL loss was the most obvious difference between the two diseases and should be primarily considered when distinguishing between CON and NTG. In CON, the optic atrophy occupies a horizontal band across the disk, is generally wider nasally than temporally, and is known as band atrophy or bowtie atrophy in chiasmal compression.⁶ In contrast, vertical elongation of the cup with thinning of the neuroretinal rim (NRR) and RNFL in the superior and inferior poles is characteristic of glaucoma. This difference has also been reported in several studies of ischemic optic neuropathy.^45–47 Our results also corroborate this different RNFL loss pattern. At the same time, the different involvement patterns and degrees of RNFL loss may also affect comparisons between diseases. Therefore, for the differential diagnosis between CON and NTG, we suggest first examining the topographic pattern of RNFL loss using all available modalities, including VF tests, photographs, and OCT. In addition, OCTA may provide useful additional data for visualizing local abnormalities, especially when analyzed as a whole en face image, which could be intuitively correlated with other tests in addition to the numerical results of the VD calculation. 

Our study has several limitations. First, the sample size was small. Nevertheless, it was challenging to recruit CON patients with a chronic follow-up status and glaucoma patients who had damage approaching the macular. Moreover, the results obtained from highly controlled comparisons may be more valuable than those obtained from uncontrolled studies involving a larger number of patients. Second, we used an arbitrary cut-off for the extent of damage in the macular GCIPL thickness maps. However, we also compared the average thickness, and the distinct halved pattern of vertical or horizontal loss would be sufficient for the purpose of our study. Third, the OCTA scan area was limited, resulting in restricted information. Although we used 3 × 3 mm² scans, larger 6 × 6 mm² or 9 × 9 mm² scans are available, which could potentially provide better insight into the changes. Nevertheless, as the current OCTA successfully demonstrated marked nasal VD loss in the CON group, the scan size may not impair the validity of the key findings. 

In conclusion, we observed a significantly lower peripapillary VD in patients in the CON group than in those in the NTG group using OCTA, under similar mean OCT thicknesses of pRNFL and macular GCIPL. These findings illustrate the potential utility of OCTA that may successfully complement OCT in relation to different topographic patterns of optic neuropathy and may enhance our understanding of the possible mechanisms of microvascular damage in different optic neuropathies. 

Disclosure: E.J. Lee, None; J.C. Han, None; C. Kee, None; K.-A. Park, None; D.-S. Kong, None; S.D. Hong, None