Vol 7 (2022): Continuous Publishing
Original paper
Published online: 2022-03-17

open access

Page views 5191
Article views/downloads 1009
Get Citation

Connect on Social Media

Connect on Social Media

Original paper

DOI: 10.5603/OJ.2022.0002

Quantitative assessment of optic disc photographs in normal and open-angle glaucoma patients

Taoufik Abdellaoui1Yassine Malek2Houda Brarou2Fouad Elasri2Yassine Mouzari2Karim Reda2Abdelbarre Oubaaz2
1Department of Ophthalmology, Med-V Military Hospital, Sidi Mohamed Ben Abdellah University, Fes, Morocco
2Department of Ophthalmology, Med-V Military Hospital, Med-V University, Rabat, Morocco

Corresponding author:

Abdellaoui Taoufik, Appt 4, Immeuble 48, Massira 1, Temara, Morocco, 10045; e-mail: rowman_xrd@hotmail.com

This article is available in open access under Creative Common Attribution-Non-Commercial-No Derivatives 4.0 International (CC BY-NC-ND 4.0) license, allowing to download articles and share them with others as long as they credit the authors and the publisher, but without permission to change them in any way or use them commercially

ABSTRACT
Background: The purpose of the study was to quantitively assess the optic nerve head (ONH) parameters from fundus photographs in normal and open-angle glaucoma patients and to compare them with those provided by spectral-domain optical coherence tomography (SD-OCT).
Material and methods: This study compares 30 glaucomatous eyes to 30 healthy control eyes. One eye from each subject was randomly enrolled. From color photographs, different parameters were measured using image processing software (Adobe Photoshop CS6) after delimiting the boundaries of the optic disc and the excavation. The correlation between these measurements and those obtained by SD-OCT was evaluated.
Results: Glaucomatous and normal patients groups were comparable in terms of age (p = 0.94), sex (p = 0.57), presence of diabetes (p = 0.52), hypertension (p = 0.40), and smoking (p = 0.67). The areas of the optic disc and the cup were significantly larger in glaucomatous patients (p = 0.004 and p < 0.001, respectively). The area of the neuroretinal rim was smaller in glaucomatous patients (p < 0.001). The vertical and horizontal cup-to-disc ratios were larger in glaucomatous patients (p < 0.001). The thicknesses of the rim in the four meridians were significantly reduced in the glaucoma group. The “ISNT” rule was fully respected in 87% of normal eyes and in only 2 cases (7%) of the glaucoma group (p < 0.001). There was an excellent correlation between different measurements obtained on photography and those provided by the SD-OCT. Pearson’s correlation coefficient was R = 0.95 (p <0.0001) for the optic disc area, R = 0.94 (p < 0.0001) for the rim area, and R = 0.98 (p < 0.0001) for the vertical cup-to-disc ratio.
Conclusion: Color photography is very useful in the diagnosis and monitoring of glaucoma. The determination of normative values can further corroborate its interest in this indication. Despite the relatively high interobserver variability, ONH parameters obtained on photography showed excellent correlation with those measured by OCT
Key words: photography; SD-OCT; quantitative assessment; glaucoma; optic disc
Ophthalmol J 2022; Vol. 7, 12–19

Introduction

Open-angle glaucoma is a progressive optic neuropathy characterized by retinal ganglion cell loss and structural changes in the retinal nerve fiber layer (RNFL) and optic nerve head (ONH) that may lead to visual field loss [1]. Diagnosis of glaucomatous damage is based on the ability of the clinician to detect signs of the disease through clinical evaluation of intraocular pressure (IOP), the appearance of the ONH and RNFL, and VF testing. The changes in the ONH can be described by many variables such as the size and shape of the optic disk; size, shape, and pallor of the neuroretinal rim; the size of the optic cup in relation to the area of the disc, ratio of cup-to-disc diameter and cup-to-disc area. The evaluation of the optic disc is an essential step in the diagnosis and monitoring of glaucoma. This assessment is based on quantitative and qualitative parameters. Initially, the optical disc was evaluated ophthalmoscopically by approximate measurements of its structure using a lens and a slit lamp with an adjustable slit height. These values are then multiplied by a corrective factor depending on the lens used. The main limitations of this technique are its high intra- and intergrader variability in interpreting the features of glaucomatous optic neuropathy, even among specialists [2]. Compared to ophthalmoscopic examination, photography offers the advantage of providing a permanent recording, which is very useful for documentation of the nerve’s appearance at a given time, allowing more detailed scrutiny then and later comparison for changes.

Since it was introduced in 1991, optical coherence tomography (OCT) has risen to the forefront of ocular imaging because of its ability to deliver high resolution, reproducible, quantitative assessment of the optic nerve head parameters with advanced segmentation algorithms and rapid data acquisition [3]. It is important to note that OCT does not replace fundus photography in glaucoma screening and diagnosis. The two imaging modalities complement one another. Used in conjunction with OCT and visual field, optic disc photography improved glaucoma diagnosis accuracy and reduced variability [3, 4].

In this study, we evaluate the morphological profile of the optic disc in glaucomatous eyes compared to healthy eyes by performing quantitative measurements of different parameters from color photographs: the area of the optic disc, the cup and the neuroretinal rim, the vertical and horizontal cup-to-disc ratio, the width of the neuroretinal rim in its lower, upper, nasal and temporal regions. We also assess the agreement and correlation between these measurements and those obtained automatically by SD-OCT.

Materials and methods

This is a prospective study including 30 glaucomatous patients. They were compared with 30 control patients matched for age, gender, and vascular risk factors. It was conducted in the ophthalmology department of the Military Hospital Med-V of Rabat in Morocco between January and March 2018. The study was approved by the review board and adhered to the tenets in the Declaration of Helsinki.

All subjects underwent a full ophthalmological examination with intraocular pressure (IOP) measurement using Goldmann’s applanation tonometer, a gonioscopic examination, fundus examination after pupillary dilation, OCT of the optic disc, and automated perimetry (24-2 standard automated perimetry visual field obtained with the SITA-Standard Automated Perimetry strategy (Humphrey VF Analyzer; Carl Zeiss Meditec).

For the “glaucoma” group, we included patients followed up for primary open-angle glaucoma with:

age over 45 years old;
IOP (before treatment) > 21 mm Hg with or without glaucomatous abnormality of the optic disc in the biomicroscopic examination, with or without detectable deficit with OCT;
visual field defects confirmed on at least two tests;
open iridocorneal angle.

For the “control” group, the controls were selected from patients presenting for a reason other than glaucoma (prescription of glasses, ocular surface disorders) during the same period with:

age over 45 years-old;
IOP21 mm Hg;
normal visual field;
open iridocorneal angle.

From the two groups, we excluded patients with:

history of non-glaucomatous optic neuropathy;
eyes with severe myopic degeneration, severe peripapillary atrophy, optic disc anomalies such as optic disc coloboma, optic disc drusen, optic disc edema, or optic nerve hypoplasia or atrophy;
spherical refractive error over six diopters or astigmatism over three diopters;
unilateral glaucoma (impossibility of randomization);
poor-quality OCT scans (signal strength < 7/10).

All color photographs were taken on the same camera (Topcon TRC-50IX) at the same angle of coverage of 50°. The SD-OCT images of the optic nerve head were obtained with the commercial version of the Zeiss Cirrus 4000 HD-OCT instrument, Software version 6.0.2.81

The different measurements were carried out by the same blinded operator. The patient’s identity, clinical information, SD-OCT images, and visual fields were not available to the reader of photographs. We used an image processing software: Adobe Photoshop CS6 extended. After delimiting the boundaries of the optic disc and the excavation by a senior reader, we measured: the areas of the optic disc, the excavation, and the neuroretinal rim; the vertical and horizontal diameter of the optic disc, and the width of the rim in its lower, upper, nasal and temporal regions (Fig. 1). The measurements in pixels were converted to an area (square millimeters) using a conversion factor. To find this conversion factor, representative photographs were obtained with the Topcon camera, and SD-OCT images were registered. From these, three pairs with excellent registration were chosen, and from identical portions of the two images, it was calculated that each pixel in the color photographs represented 0.0000103 mm2 or 103 μm2 in the SD-OCT image.

Abdel-1.jpg
Figure 1. A. Optic nerve head photography; B. The reader marks outlines of the optic disc and the cup; C. the reader marks the vertical diameter (VD) of the optic disc and the cup, the neuroretinal rim width at the inferior (I) and the superior (S) positions; D. the reader marks the Horizontal diameter (HD) of the optic disc and the cup, the neuroretinal rim width at the nasal (N) and the temporal (T) positions

SPSS software version 20 was used for statistical analysis. The Kolmogorov-Smirnov test was used to assess the normal distribution of the variables. The significance of the differences in the findings was determined by Student’s t-test, Mann-Whitney U test, Wilcoxon test, Chi-square test (c2). The Pearson correlation method was used to analyze the correlation of measurements with photography and OCT. A p-value less than 0.05 was considered statistically significant.

Results

The mean age was 58±15 years. Male/female ratio was 41/19. There were no significant differences between the two groups concerning age (p = 0.94), sex (p = 0.57), diabetes (p = 0.52), hypertension (p = 0.40), and smoking (p = 0.67). The baseline characteristics of the patients are summarized in Table 1.

Table 1. Baseline characteristics of subjects by groups

Characteristics

Glaucoma group
(n = 30)

Controls
(n = 30)

p

Age*

58.8 ± 9

58.2 ± 17

0.94

Sex (Male/female)

22/8

20/10

0.57

Diabetes**

16.7

23.3

0.52

Hypertension**

26.7

36.7

0.40

Smoking**

6.7

13.3

0.67

Mean deviation [dB]* (visual field)

–7.29 ± 3.20

–1.12 ± 0.59

< 0.001

The dimensions of the optic disc were significantly larger in glaucomatous patients; the average optic disc area was 2.52 ± 0.28 mm2 in the glaucoma group versus 2.12 ± 0.35 mm2 in the control group (p = 0.004). The vertical and horizontal diameters of the disc were larger in the glaucoma group (p = 0.01 and p = 0.002, respectively). The cup area was significantly larger in glaucomatous patients (p < 0.001). The rim area was smaller in glaucomatous patients (p < 0.001). The vertical and horizontal cup-to-disc ratios were higher in glaucomatous patients (p < 0.001). The width of the rim in glaucomatous patients was significantly smaller in its lower (p < 0.001), upper (p < 0.001), nasal (p = 0.01) and temporal regions (p = 0.02). The ISNT rule was fully respected in 87% of the control group and only in 7% of the glaucoma group (p < 0.001). The measurements obtained from the photographs are presented in Table 2.

Table 2. Optic disc parameters in the study groups measured by photography

Parameter

Glaucoma group
(n = 30)

Controls
(n = 30 )

p

Area* [mm2]

Optic disc

Cup

Rim

2.52 ± 0.28

1.58 ± 0.36

0.87 ± 0.18

2.12 ± 0.35

0.8 ± 0.12

1.33 ± 0.27

0.004

< 0.001

< 0.001

Disc diameter* [mm]

Vertical

Horizontal

1.84 ± 0.12

168 ± 0.11

1.71 ± 0.13

1.48 ± 0.15

0.01

0.002

Cup-to-disc ratio

Vertical

Horizontal

0.60 ± 0.14

0.54 ± 0.13

0.34 ± 0.15

0.28 ± 0.09

< 0.001

< 0.001

Rim width* [μm]

Inferior

Superior

Nasal

Temporal

414 ± 111

394 ± 121

464 ± 121

353 ± 89

613 ± 81

560 ± 81

532 ± 61

414 ± 70

< 0.001

< 0.001

0.01

0.02

ISNT rule intact**

2 (7)

26 (87)

< 0.001

We compared the ONH parameter measurements obtained on photographs (optic disc area, rim area, vertical cup-to-disc ratio) with those automatically provided by SD-OCT. The mean areas of the optic discs and the neuroretinal rim determined by photography were larger by approximatively 8% and 10%, respectively (p < 0.001). On the contrary, the mean cup-to-disc area ratio was slightly smaller in photography by approximately 4,5% (Tab. 3). However, there was an excellent correlation between the different parameters measured on photographs and those provided by SD-OCT. Pearson’s correlation coefficient was R = 0.95 (p < 0.0001) for the optic disc size, R = 0.94 for the rim area (p < 0.0001) and R = 0, 98 (p < 0.0001) for the vertical cup-to-disc ratio (Tab. 4, Fig. 2).

Table 3. Comparison between optic nerve head parameters obtained by photography and spectral-domain optical coherence tomography (SD-OCT)

Parameter

Photography

SD-OCT

p

Optic disc area [mm2]

Glaucoma group

Controls

2.52 ± 0.28

2.12 ± 0.35

2.35 ± 0.23

1.95 ± 0.29

< 0.001

< 0.001

Rim area [mm2]

Glaucoma group

Controls

0.87 ± 0.18

1.33 ± 0.26

0.80 ± 0.18

1.22 ± 0.21

< 0.001

< 0.001

Vertical cup-to-disc ratio

Glaucoma group

Controls

0.60 ± 0.14

0.34 ± 0.15

0.62 ± 0.15

0.37 ± 0.10

0.01

0.001

Table 4. Correlation between optic nerve head parameters obtained by photography and spectral-domain optical coherence tomography (SD-OCT)

Parameter

Photography

SD-OCT

Pearson’s correlation coefficient (R)

p

Disc area [mm2]

2.38 ± 0.35

2.20 ± 0.33

0.95

< 0.001

Rim Area [mm]

1.11 ± 0.33

1.01 ± 0.28

0.94

< 0.001

Vertical cup-to-disc ratio

0.46 ± 0.19

0.48 ± 0.19

0.98

< 0.01

03-Taoufik-2.png
Figure 2. Correlation between the photographic measurements and spectral-domain optical coherence tomography (SD-OCT)

Discussion

Careful observation of ONH is of great importance in the diagnosis and follow-up of glaucoma. Various techniques are available for estimating optic disc size. Each has specific strengths and limitations when applied to certain types of clinical and research objectives. Some of the measurement techniques are more applicable to clinical practice than others [5]. Many studies have shown that qualitative and quantitative assessment of optic nerve photography is very useful for the detection of glaucoma with high sensitivity and specificity [6–9] Comparisons have been made between human estimation and machine imaging with analysis software [10], as well as between different machines [11]. In the current study, we investigated the performance of the clinical evaluation, as represented by color photographs of the optic disc and its agreement with measurements obtained with SD-OCT.

Several studies have found equal optic disc sizes in both normal and glaucomatous eyes [12] while others have demonstrated larger disc areas in glaucomatous eyes.[13, 14] The optic disc area in the present study was significantly larger in the glaucomatous eyes. It was suggested that the large optic disc was one among other factors predisposing to glaucomatous optic nerve fiber loss even in the presence of a statistically normal intraocular pressure [15] Tuulonen et al. reported that large discs could be damaged by low intraocular pressure because of the property of the extracellular matrix [16]. Uysal et al. compared 70 eyes with early or moderate glaucomatous damage and 70 healthy eyes: mean disc area was significantly larger in the glaucoma group [13]. Mehdizadeh et al. presented a theoretical explanation for this finding. He proposed that biomechanical factors such as tensile stress (s) in the optic nerve head are the primary insult that leads to retinal ganglion cell loss. Tensile stress (s) of the wall of a sphere is calculated by the formula: s = PR/2t, where P is pressure, R is the inner radius of the sphere, and t is the wall thickness; then tensile stress and radius are directly related [17]. Considering that as a part of a sphere, the larger optic disc has a larger inner radius of curvature than that of a smaller disc, in a given constant IOP and lamina cribrosa thickness, the larger disc will suffer more tensile stress than that of a smaller disc. Therefore, a large optic disc is more susceptible to IOP rise than a small optic disc [18].

It has been shown that abnormalities in the appearance of the optic disc may precede visual field defects. These abnormalities include a high cup-to-disc ratio, an unusually small area of the neuroretinal rim, and an abnormal shape of the rim [19]. The estimation of the cup-to-disc ratio is one of the most frequently performed clinical methods for a simple assessment of the optic disc in glaucoma diagnosis and follow-up [5]. The vertical ratio is preferred to the horizontal ratio as the thinning of the rim and the optic cup enlargement in glaucomatous eyes may not be really concentric but, in fact, more vertical [12]. The studies are unanimous that the vertical cup-to-disc ratio is statically larger in glaucomatous eyes, which makes it one of the most valuable optic disc variables for detection and follow-up of glaucomatous optic nerve damage. The estimation of cup-to-disc is more practical with photography than biomicroscopy since it provides a permanent recording of the nerve’s appearance at a given time, allowing more detailed scrutiny and later comparison for changes. The use of software to measure this ratio on photographs makes this estimation more precise.

The rim area is of particular interest because, like the retinal nerve fiber layer thickness, it reflects the number of axons passing out of the eye [20]. In advanced glaucomatous optic nerve damage, the area of the neuroretinal rim progressively diminishes, and its form continuously changes. Like the present study, several studies reported that the average rim area was significantly lower in glaucomatous eyes than in healthy eyes and that the neuroretinal rim area had good diagnostic abilities [21, 22].

The neuroretinal rim in normal eyes shows a characteristic configuration. It is usually broadest in the inferior rim, followed by the superior and nasal rims, and thinnest in the temporal disc region. This pattern of rim width is known as the ISNT rule (inferior > superior > nasal > temporal). Harizman et al. evaluated the ISNT rule on stereoscopic disc photography. The rule was intact in 79% of normal eyes and 28% of glaucomatous eyes (p < 0.001).[23] In our study, this rule was intact in only 7% of glaucomatous eyes, while it was respected in 87% of controls (p < 0.001).

The measurements obtained on photographs were different from those measured by SD-OCT. Compared to SD-OCT, photography overestimates the disc and rim areas. The cup-to-disc ratio is also slightly different between the two methods. The discrepancy between photograph determinations of optic disc size and the determination from SD-OCT may be due to a different outlining of the optic disc boundaries. this finding can be explained by the fact that the SD-OCT considers the optic disc margin to be the opening in Bruch’s membrane, whereas, on photography, the edge of Bruch’s membrane is not always evident, and the designation of the optic disc boundary can be influenced by the contrast of optic disc tissue with surrounding peripapillary tissues [20]. Thus, photography tends to enlarge the boundary of the optic disc. The boundary of the cup is also difficult to determine, and the central retinal vessel trunk along its inner surface also makes the margins ambiguous [10, 20].

Despite being different, we found a very good linear correlation between the measurements of the different parameters obtained by photography and SD-OCT. Sharma et al. found a good and statistically highly significant correlation between measurements obtained on stereoscopic photographs after manual tracing of the optic disc and cup margins and those obtained with automatic analysis by SD-OCT [20]. The presence of this linear correlation means that we can rely on measurements by photography. However, there are several limitations to the use of this technique of measurement, it is time-consuming, and it depends upon subjective judgment of the optic disc boundaries.

This study presents certain biases: a selection bias due to the fact that the control group was included from the hospital and then would not be representative of the general population, and an evaluation bias given that the delimitation of the optic disc and the excavation boundaries was carried out manually, and we did not test the reproducibility of the ONH parameter measurements, which can constitute a measurement bias due to the possibility of operator-dependent variation. However, this bias was reduced by the fact that this analysis was carried out by the same blinded operator. Despite being prospective, our study has certain limits, namely, the small size of the study population, not including all age ranges. Larger cohorts of patients would provide more precise values and establish a normative database for different age groups.

Conclusion

Comparison of serial optic disc photographs has long been considered the gold standard for assessing glaucoma progression. The use of software to measure different parameters on photographs makes this comparison more precise. We believe that the conception of an image processing software integrated into portable ophthalmoscopes, able to detect the optic nerve head and its different components according to a colorimetric scale and to perform measurements of different parameters could be an interesting fast, and inexpensive technique, particularly for glaucoma mass screening.

Conflicts of interest

The authors declare that there is no conflict of interest regarding the publication of this paper.

References

  1. Güerri N, Polo V, Larrosa JM, et al. Performance of imaging devices versus optic disc and fiber layer photography in a clinical practice guideline for glaucoma diagnosis. Eur J Ophthalmol. 2012; 22(4): 554–562, doi: 10.5301/ejo.5000075, indexed in Pubmed: 22081672.
  2. Jampel HD, Friedman D, Quigley H, et al. Agreement among glaucoma specialists in assessing progressive disc changes from photographs in open-angle glaucoma patients. Am J Ophthalmol. 2009; 147(1): 39–44.e1, doi: 10.1016/j.ajo.2008.07.023, indexed in Pubmed: 18790472.
  3. Myers JS, Fudemberg SJ, Lee D. Evolution of optic nerve photography for glaucoma screening: a review. Clin Exp Ophthalmol. 2018; 46(2): 169–176, doi: 10.1111/ceo.13138, indexed in Pubmed: 29280542.
  4. Alhadeff PA, De Moraes CG, Chen M, et al. The Association Between Clinical Features Seen on Fundus Photographs and Glaucomatous Damage Detected on Visual Fields and Optical Coherence Tomography Scans. J Glaucoma. 2017; 26(5): 498–504, doi: 10.1097/IJG.0000000000000640, indexed in Pubmed: 28333890.
  5. Hoffmann EM, Zangwill LM, Crowston JG, et al. Optic disk size and glaucoma. Surv Ophthalmol. 2007; 52(1): 32–49, doi: 10.1016/j.survophthal.2006.10.002, indexed in Pubmed: 17212989.
  6. Schultz RO, Radius RL, Hartz AJ, et al. Screening for glaucoma with stereo disc photography. J Glaucoma. 1995; 4(3): 177–182, indexed in Pubmed: 19920665.
  7. Badalà F, Nouri-Mahdavi K, Raoof DA, et al. Optic disk and nerve fiber layer imaging to detect glaucoma. Am J Ophthalmol. 2007; 144(5): 724–732, doi: 10.1016/j.ajo.2007.07.010, indexed in Pubmed: 17868631.
  8. Ohkubo S, Takeda H, Higashide T, et al. A pilot study to detect glaucoma with confocal scanning laser ophthalmoscopy compared with nonmydriatic stereoscopic photography in a community health screening. J Glaucoma. 2007; 16(6): 531–538, doi: 10.1097/IJG.0b013e31804a5e97, indexed in Pubmed: 17873714.
  9. Deleón-Ortega JE, Arthur SN, McGwin G, et al. Discrimination between glaucomatous and nonglaucomatous eyes using quantitative imaging devices and subjective optic nerve head assessment. Invest Ophthalmol Vis Sci. 2006; 47(8): 3374–3380, doi: 10.1167/iovs.05-1239, indexed in Pubmed: 16877405.
  10. Samarawickrama C, Pai A, Huynh SC, et al. Measurement of optic nerve head parameters: comparison of optical coherence tomography with digital planimetry. J Glaucoma. 2009; 18(8): 571–575, doi: 10.1097/IJG.0b013e3181996da6, indexed in Pubmed: 19826383.
  11. Medeiros FA, Zangwill LM, Bowd C, et al. Comparison of the GDx VCC scanning laser polarimeter, HRT II confocal scanning laser ophthalmoscope, and stratus OCT optical coherence tomograph for the detection of glaucoma. Arch Ophthalmol. 2004; 122(6): 827–837, indexed in Pubmed: 15197057.
  12. Jonas JB, Gusek GC, Naumann GO. Optic disc morphometry in chronic primary open-angle glaucoma. I. Morphometric intrapapillary characteristics. Graefes Arch Clin Exp Ophthalmol. 1988; 226(6): 522–530, doi: 10.1007/BF02169199, indexed in Pubmed: 3209079.
  13. Uysal Y, Bayer A, Erdurman C, et al. Sensitivity and specificity of Heidelberg Retinal Tomography II parameters in detecting early and moderate glaucomatous damage: effect of disc size. Clin Exp Ophthalmol. 2007; 35(2): 113–118, doi: 10.1111/j.1442-9071.2006.01393.x, indexed in Pubmed: 17362450.
  14. Girkin CA, McGwin G, McNeal SF, et al. Racial differences in the association between optic disc topography and early glaucoma. Invest Ophthalmol Vis Sci. 2003; 44(8): 3382–3387, doi: 10.1167/iovs.02-0792, indexed in Pubmed: 12882785.
  15. Jonas JB, Stürmer J, Papastathopoulos KI, et al. Optic disc size and optic nerve damage in normal pressure glaucoma. Br J Ophthalmol. 1995; 79(12): 1102–1105, doi: 10.1136/bjo.79.12.1102, indexed in Pubmed: 8562544.
  16. Tuulonen A, Airaksinen PJ. Optic disc size in exfoliative, primary open angle, and low-tension glaucoma. Arch Ophthalmol. 1992; 110(2): 211–213, doi: 10.1001/archopht.1992.01080140067029, indexed in Pubmed: 1736870.
  17. Bellezza AJ, Hart RT, Burgoyne CF. The optic nerve head as a biomechanical structure: initial finite element modeling. Invest Ophthalmol Vis Sci. 2000; 41(10): 2991–3000, indexed in Pubmed: 10967056.
  18. Mehdizadeh M, Nowroozzadeh MH. Optic disc size and glaucoma. Clin Exp Ophthalmol. 2008; 36(4): 395–396, doi: 10.1111/j.1442-9071.2008.001778.x, indexed in Pubmed: 18700934.
  19. Jonas JB, Bergua A, Schmitz-Valckenberg P, et al. Ranking of optic disc variables for detection of glaucomatous optic nerve damage. Invest Ophthalmol Vis Sci. 2000; 41(7): 1764–1773, indexed in Pubmed: 10845597.
  20. Sharma A, Oakley JD, Schiffman JC, et al. Comparison of automated analysis of Cirrus HD OCT spectral-domain optical coherence tomography with stereo photographs of the optic disc. Ophthalmology. 2011; 118(7): 1348–1357, doi: 10.1016/j.ophtha.2010.12.008, indexed in Pubmed: 21397334.
  21. Mwanza JC, Oakley JD, Budenz DL, et al. Cirrus Optical Coherence Tomography Normative Database Study Group. Ability of cirrus HD-OCT optic nerve head parameters to discriminate normal from glaucomatous eyes. Ophthalmology. 2011; 118(2): 241–248.e1, doi: 10.1016/j.ophtha.2010.06.036, indexed in Pubmed: 20920824.
  22. Hwang YH, Kim YY. Glaucoma diagnostic ability of quadrant and clock-hour neuroretinal rim assessment using cirrus HD optical coherence tomography. Invest Ophthalmol Vis Sci. 2012; 53(4): 2226–2234, doi: 10.1167/iovs.11-8689, indexed in Pubmed: 22410556.
  23. Harizman N, Oliveira C, Chiang A, et al. The ISNT rule and differentiation of normal from glaucomatous eyes. Arch Ophthalmol. 2006; 124(11): 1579–1583, doi: 10.1001/archopht.124.11.1579, indexed in Pubmed: 17102005.