Figures
Abstract
Main Objective
The thinning of prelaminar tissue and prelamina cupping is known to occur by ischemia, as we see in anterior ischemic optic neuropathy. Since normal tension glaucoma (NTG) is thought to be more related to vascular factor than in primary open-angle glaucoma (POAG), we hypothesized that prelamina thinning may occur prominently in NTG patients. This study investigated the difference in prelaminar tissue thickness between patients with POAG and NTG and verified the factors related to prelaminar thinning.
Methods
Complete ophthalmic examination including standard automatic perimetry was performed in all patients. The prelaminar tissue thickness was measured in all patients by performing enhanced depth imaging with a Heidelberg Spectralis Optical Coherence Tomography. The retinal nerve fiber layer and optic nerve head parameters were obtained using the Heidelberg Retina Tomography II and Cirrus Optical Coherence Tomography. Various ocular factors and their relationships with prelaminar thickness were analyzed.
Results
The mean prelaminar tissue thickness was significantly thinner in patients with POAG than in those with NTG. The difference in the prelaminar thickness between patients with POAG and those with NTG was greater in the early field defect group than in the moderate and severe field groups. In multivariate analysis, the mean prelaminar thickness was related to the intraocular pressure, mean deviation, cup-disc ratio, and cup volume.
Citation: Jung YH, Park H-YL, Jung KI, Park CK (2015) Comparison of Prelaminar Thickness between Primary Open Angle Glaucoma and Normal Tension Glaucoma Patients. PLoS ONE 10(3): e0120634. https://doi.org/10.1371/journal.pone.0120634
Academic Editor: Ted S. Acott, Casey Eye Institute, UNITED STATES
Received: July 24, 2014; Accepted: January 26, 2015; Published: March 20, 2015
Copyright: © 2015 Jung et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The prelaminar region, also termed the anterior portion of the lamina cribrosa, comprises bundles of retinal ganglion cell (RGC) axons, astrocytes, capillaries, and extracellular material [1,2]. In patients with glaucoma, the principal site of RGC axonal insult has generally been acknowledged to be the laminar region of the optic nerve head [3–5]. However, there is growing evidence that reversal of optic nerve cupping after an acute reduction of intraocular pressure (IOP) occurs due to changes in both the lamina and prelaminar zone.
Parrish II et al. [6] reported reversal of optic nerve head cupping 5 years after surgical reduction of IOP and suggested the possibility of prelaminar neural tissue thickening. Reis et al. [7] also reported thickening of the prelaminar tissue after lowering the IOP by surgery in patients with POAG. Barrancos et al. [8] studied 28 patients with POAG who underwent nonpenetrating deep sclerectomy and concluded that cupping reversal was mainly due to changes in prelaminar tissue thickness. In addition, Agoumi et al. [9] reported thinning of the prelaminar tissue after acute IOP elevation in patients with glaucoma. Based on these studies, it can be suggested that the prelaminar thickness is influenced by the IOP; it is compressed when the IOP increases and becomes thicker when the IOP decreases.
Other studies have demonstrated the effect of ischemia on the prelaminar region. The prelaminar region comprises neural and connective tissue, both of which can become thinned by ischemia [10]. Henkind et al. [11] described atrophy of the prelaminar tissue in the histological findings of a 67-year-old woman with arterial anterior ischemic optic neuropathy (AAION). Danesh-Meyer et al [12]. compared the optic disc morphology among patients with open-angle glaucoma, arteritic anterior ischemic optic neuropathy, and nonarteritic anterior ischemic optic neuropathy (NAION) and demonstrated that at similar degrees of retinal ganglion cell axon loss, there was more dramatic posterior excavation of the lamina in patients with open-angle glaucoma than in patients with AAION and NAION. Furthermore, patients with AAION who had greater ischemic damage than patients with NAION showed more severe changes in the prelaminar tissue than did patients with NAION. Thus, glaucomatous optic disc cupping is thought to be laminar cupping, whereas disc cupping resulting from ischemia of the optic disc may be prelaminar cupping.
In POAG, the mechanism of optic neuropathy is predominantly associated with the IOP. In NTG, although IOP is still an important factor, other pressure-independent factors such as an increased frequency of migraine headaches, Raynaud’s phenomenon, and sleep apnea have been observed, suggesting a vascular role in the nerve damage of patients with NTG [13]. If there is a greater vascular component in NTG than in POAG, disc cupping in patients with NTG may be characterized by a higher proportion of prelaminar cupping than that in patients with POAG. Therefore, in the present study, we compared the prelaminar tissue thickness using enhanced depth imaging (EDI) spectral domain (SD) Optical Coherence Tomography (OCT) between patients with POAG and those with NTG to verify whether mechanical or ischemic factors influence the prelaminar thickness. In addition, various clinical parameters were investigated to define the factors affecting the prelaminar tissue thickness.
Materials and Methods
Subjects
A retrospective medical record review of patients who visited Seoul St. Mary’s Hospital, College of Medicine, Catholic University of Korea, Seoul, Korea, between May and September 2013 was performed. All procedures were carried out in accordance with the Declaration of Helsinki. This study was approved by the institutional review board of Seoul St. Mary’s Hospital. The institutional review board waived the need for a written consent from the participants, because of the retrospective design. Patient information was anonymized and de-identified prior to analysis. When both eyes of the patient were eligible for the study, one eye was randomly selected for inclusion. All participants underwent a comprehensive ophthalmic examination including slit-lamp biomicroscopy, best-corrected visual acuity measurement, Goldmann applanation tonometry, gonioscopy, dilated funduscopic examination, color disc photography, red-free retinal nerve fiber layer photography (VX-10; Kowa Optimed, Tokyo, Japan), ultrasound pachymetry (Tomey Corporation, Nagoya, Japan) to measure central corneal thickness, achromatic automated perimetry using the Swedish Interactive Threshold Algorithm 24–2 (Humphrey Visual Field Analyzer; Carl Zeiss Meditec, Inc., Dublin, CA), axial length measurement using ocular biometry (IOL Master; Carl Zeiss Meditec, Inc., Dublin, CA, USA), Cirrus OCT imaging (Carl Zeiss Meditec, Inc., Dublin, CA, USA), Heidelberg Retina Tomograph II imaging (HRT; Heidelberg Engineering, Heidelberg, Germany), and EDI-OCT (Spectralis; Heidelberg Engineering, Heidelberg, Germany). Experienced ophthalmologists performed the OCT to acquire EDI images. For Cirrus OCT, images that are well focused and well centered without eye motion and with signal strengths greater than 6 were used in the analysis. For HRT, images with standard deviation < 30 μm were accepted.
The inclusion criteria were a best-corrected visual acuity of 20/40 or better with a spherical refraction within ±6 diopters, cylinder correction within ±3 diopters, and axial length of 22 to 25 mm. Patients with at least 2 years of follow-up comprising more than three visual field tests were chosen. Those with a history of previous intraocular surgery or any other ophthalmic disease that could cause visual field defects were excluded.
Both POAG and NTG were defined as the presence of a normal anterior chamber and open angle on slit-lamp and gonioscopic examinations, a glaucomatous optic disc (diffuse or focal thinning of the neuroretinal rim), and an abnormal visual field consistent with glaucoma that were confirmed by at least two reliable visual field examinations. In patients with POAG, untreated IOP was >21 mmHg, whereas in patients with NTG, IOP was ≤21 mmHg without any topical medical treatment. Repeated IOP measurements were performed at least four times per patient on different days at different time points for the diagnosis of NTG. The average of at least five IOP measurements under treatment during the previous 12-month period was used as the mean IOP.
A glaucomatous visual field change was defined as demonstration of the following criteria: (1) a cluster of three or more nonedge points with a probability of <5% on a pattern deviation plot and with one of these points having a probability of <1%; (2) glaucoma hemifield test results outside of the normal limits; or (3) a pattern standard deviation of <5%. Visual field defects had to be repeatable on at least two consecutive tests. Glaucoma was categorized into three subgroups based on the mean deviation (MD) of the visual field according to the modified Hodapp—Anderson—Parrish grading scale as follows [14]: early glaucoma, MD ≥ –6 dB; moderate glaucoma, –6 dB < MD ≤ –12 dB; and severe glaucoma, MD ≤ –12 dB. A reliable visual field test was defined as a false-positive error rate of <15%, a false-negative error rate of <15%, and a fixation loss of <20%.
Measurement of prelaminar tissue thickness
SD-OCT imaging was performed with the Heidelberg Spectralis OCT (Spectralis software v. 5.1.1.0, Eye Explorer Software 1.6.1.0; Heidelberg Engineering) in the EDI mode after pupillary dilation. The technique has previously been described in detail [14]. The EDI-OCT B-scans around the optic nerve head were obtained using the Heidelberg Spectralis OCT with a 20° retinal window. To center the disc in the 10° × 15° rectangle, an internal nasal fixation light was used while the instrument obtained 512 A-scans of the optic nerve head using a 6-mm-long line at approximately 50 μm intervals. The scan of the optic nerve head resulted in approximately 30 cross-sectional B-scans, of which only those that visualized the prelaminar regions were included. For EDI-OCT images, images with acceptable scans, which require quality score > 15 (range, 0–40), and those with clear fundus image with a good optic disc and scan circle visibility during image acquisition, clearly visible retinal nerve fiber layer (RNFL) without interruptions, and continuous scan pattern with no missing or blank areas.
To measure the prelaminar thickness, a perpendicular line was drawn at the center and at 100μm nasally and temporally from a reference line connecting both ends of Bruch’s membrane opening. The prelaminar thickness was measured along this perpendicular line from the anterior border of the reflective region to the anterior border of the highly reflective region, which is the anterior laminar border. For each patient, the mean of 3 values was defined as the prelaminar thickness of the B-scan. The average of prelaminar thickness of each B-scan was used as the mean prelaminar thickenss (Fig. 1).
The entire optic nerve head was scanned horizontally with 50-μm intervals. Only those that visualized the prelminar regions (green lines) were included. From a reference line connecting both ends of Bruch’s membrane opening, a perpendicular line was drawn at the center and at 100μm nasally and temporally in each B-scan. For each patient, the mean of 3 prelaminar thickness measurements was defined as the prelaminar thickness of the B-scan. The average of prelaminar thickness of each B-scan was used as the mean prelaminar thickenss
To evaluate the interobserver reproducibility of our measuring method, 15 randomly selected SD-OCT datasets were evaluated by two independent examiners (YJ and H-YLP), and the intraclass correlation coefficient was calculated. The interobserver intraclass correlation coefficient for measuring the prelaminar tissue thickness was 0.924.
Statistical analysis
An independent t test was performed for continuous variables and Chi-squared test for categorical data to determine the significance of differences between the two groups. When the Levene’s test for equality of variances was statistically significant, indicating the variances were not equal between the two groups, the Welch-Satterthwaite correction was used to account for this. Univariate and multivariate regression analyses were performed to identify factors related to prelaminar thickness. Variables with a significance of P < 0.10 in the univariate regression analysis were included in the multivariate regression analysis. The Statistical Package for the Social Sciences for Windows (v. 12.0.0; SPSS Inc., Chicago, IL) was used for all statistical analyses. Values of P < 0.05 were considered statistically significant.
Results
EDI-OCT images were obtained in 176 patients; however, 7 (4.0%) patients (3 POAG and 4 NTG patients) with unclear prelaminar and laminar measurements were excluded from the analysis. A total of 169 patients (68 with POAG and 101 with NTG) were included in the analysis.
Patients’ baseline characteristics
The patients’ characteristics are summarized in Table 1. There were no statistically significant differences in age, gender, mean intraocular pressure, spherical equivalent, axial length, or central corneal thickness between the POAG and NTG groups. POAG-affected eyes had an average mean deviation of—6.72 dB, which was similar to that of NTG-affected eyes (-6.43 dB, P = 0.674). All OCT and HRT parameters, including the RNFL average thickness and vertical cup/disc ratio, were similar between the two groups (Table 2).
Prelaminar thickness as measured by EDI SD OCT
The mean (SD) prelaminar thickness was thinner in the POAG group (81.08 (22.50) μm) than in the NTG group (98.35 (32.31) μm) (P = 0.000) with statistical significance (Table 3; Fig. 2). The prelaminar thickness was compared between the two groups according to the severity of damage; the mean deviation of the visual field (Table 3). Based on the mean deviation of the visual field, the prelaminar tissue was statistically significantly thinner in the POAG group (89.19 (18.74)μm) than in the NTG group (111.13 (32.92) μm) in the early group (P = 0.000). However, there were no statistically significant differences between the POAG and NTG groups in patients with moderate and severe glaucoma (P = 0.175 and P = 0.311, respectively).
In POAG-affected eyes, the mean deviation was—11.86 dB, whereas in NTG-affected eyes, the mean deviation was—11.08 dB. The prelaminar tissue was thinner in POAG-affected eyes (75 μm) than in NTG-affected eyes (88 μm). POAG = primary open-angle glaucoma; NTG = normal-tension glaucoma.
In the univariate regression analysis, IOP (P = 0.000), visual field MD (P = 0.000), average RNFL thickness (P = 0.044), rim area (P = 0.005), average cup/disc ratio (CDR) (P = 0.007), cup volume(P < 0.003), linear CDR (P = 0.0.007), rim area (P < 0.007), and cup shape measure (P = 0028) had statistically significant relationships with the prelaminar thickness (Table 4). The multivariate regression analyses included variables with P < 0.1 and were performed separately with OCT and HRT parameters due to multicollinearity. In the multivariate regression analysis including OCT parameters, IOP (P = 0.001), MD (P = 0.001), average CDR (P = 0.017), and cup volume (P = 0.001), were statistically significant predictors of the prelaminar thickness (Table 5). In the multivariate regression analysis including HRT parameters, IOP (P = 0.001) and MD (P = 0.007) were statistically significant predictors.
Relationship between IOP and prelaminar tissue thickness
The relationship between the IOP and prelaminar tissue thickness in both the POAG and NTG groups was further evaluated by linear regression analysis. The POAG and NTG groups were each subdivided based on the severity of visual field defects. In the mild subgroups, the regression coefficient was more negative in the NTG group (r = -0.436) than the POAG group (r = -0.199) with statistically significance (P = 0.040). In the moderate groups, the regression coefficients for NTG and POAG groups were-0.324 and -0.194, respectively with no statistical significance (P = 0.455). In the severe groups, there was no statistically significant difference (P = 0.872) between regression coefficients in the NTG and POAG groups (r = -0.242 and -0.167, respectively) (Fig. 3).
There was statistically more negative relationship between IOP and prelaminar thickness in NTG patients than POAG patients in the early glaucoma group (left). In the moderate (middle) and severe (right) groups, the differences were not statistically significant.
The NTG group was subdivided according to the prelaminar thickness. The mean (SD) IOP was 14.70 (2.81) mmHg in patients with a prelaminar thickness of <100 μm (n = 60) and 12.97 (2.29) mmHg in those with a prelaminar thickness of ≥100 μm (n = 41); the difference between the two subgroups was statistically significant (P = 0.002).
Discussion
We observed the differences in the prelaminar tissue thickness between patients with POAG and those with NTG using EDI-OCT images and analyzed the factors related to the prelaminar tissue thickness. The prelaminar tissue was significantly thinner in the POAG group than in the NTG group. When we used MD as a surrogate measure of RGC loss, the prelaminar tissue was statistically significantly thinner in the POAG group than in the NTG group within the early MD group. It was also thinner in the POAG group than in the NTG group within the moderate and severe MD groups, but the difference was not statistically significant.
Factors affecting the prelaminar thickness included MD and CDR, indicating that loss of neural tissue resulted in thinning of prelaminar tissue. Disc area and cup volume were also statistically significant factors affecting the prelaminar thickness. Like the laminar tissue, the prelaminar tissue may be influenced by the structural aspects of glaucoma. Furthermore, the IOP had a significant negative relationship with the prelaminar tissue thickness. The prelaminar zone comprises bundles of RGC axons, astrocytes, capillaries, and extracellular material [1,2]. At a similar degree of RGC axon loss, the mechanical force of the IOP may result in a “squeezing” effect, which could explain the difference in the prelaminar thickness between the two groups. Because the prelamina is also more compliant in the early stage of glaucoma, this effect may be more prominent in the early stage of glaucoma, as shown in our results. To the best of our knowledge, this is the first study to compare the difference in prelaminar tissue thickness between patients with POAG and those with NTG. Other studies have shown a relationship between the IOP and prelaminar tissue thickness. Reis et al. [7] reported increased prelaminar tissue thickness after glaucoma surgery in patients with POAG. They speculated that the increase in prelaminar thickness was due to an increase in blood volume or a shift of axoplasmic fluid from the peripapillary retinal nerve fibers or lamina. Lee et al. [15] reported increased prelaminar tissue thickness after trabeculectomy, which decreased the average IOP from 27.2 ± 8.9 to 10.5 ± 3.4 mmHg. However, these studies reported changes in prelaminar tissue thickness after an acute IOP change. Our study demonstrated the chronic effect of IOP on prelaminar tissue thickness and identified other factors that influence the thickness.
The difference in the negative relationship of the IOP and prelaminar tissue thickness between the POAG and NTG groups was the greatest in the early MD group. A previous study by Agoumi et al. [9] compared the prelaminar tissue between patients with glaucoma and controls in vivo after an acute IOP elevation. In their study, although their analysis focused on prelaminar tissue displacement, the prelaminar tissue thickness after an acute IOP elevation of approximately 13 mmHg in the patients with glaucoma decreased by 7.3 μm, whereas in age-matched normal controls, the thickness decreased by 20.6 μm. They explained that this decreased compliance in patients with glaucoma may have been due to tissue remodeling of the prelamina, which resulted in increased stiffness. Similarly, an explanation for our findings may be that chronically elevated IOP subjects the prelaminar tissue to consistent stress, which leads to tissue remodeling in the extracellular matrix [16–18]. In patients with advanced glaucoma, not only is there a decrease in RGC axons, but there is also increased stiffness from tissue remodeling, which results in decreased compliance [9].
The prelaminar region comprises neural tissue and connective tissue, which may become thinned by ischemia [10]. Patients with AAION who had greater ischemic damage than that of patients with NAION showed more severe changes in their prelaminar tissue than did patients with NAION at similar degrees of RGC axon loss [12]. Many reports have shown greater vascular roles in NTG than in POAG [19–21]. We hypothesized that if NTG is characterized by a more prominent vascular role than that in POAG, the prelaminar tissue may be more severely affected in NTG eyes. However, the result was the opposite. The prelaminar thickness had a negative correlation with the IOP in both NTG and POAG. This shows that the prelaminar tissue is greatly influenced by the IOP in both POAG and NTG.
Due to the retrospective design, there are only a small number of patients in the subgroups, which requires caution when interpreting these results. To our knowledge, however, this is the first study to compare the prelaminar thickness in POAG and NTG patients, and further studies will be required to assess the difference with different stages of glaucoma.
In conclusion, the prelaminar thickness is influenced by the IOP, MD, CDR, and cup volume in both patients with POAG and those with NTG. POAG-affected eyes demonstrate thinner prelaminar tissue than do NTG-affected eyes at similar levels of glaucoma severity, and the difference is greater in patients with early glaucoma. IOP may be the main pathogenic factor in both POAG and NTG.
Acknowledgments
The English in this document has been checked by at least two professional editors, both native speakers of English. For a certificate, please see: http://www.textcheck.com/certificate/F7lLjH
Author Contributions
Conceived and designed the experiments: YJ HP CP. Performed the experiments: YJ KJ. Analyzed the data: YJ HP CP. Contributed reagents/materials/analysis tools: YJ KJ. Wrote the paper: YJ HP CP.
References
- 1. Hernandez MR, Igoe F, Neufeld AH. Extracellular matrix of the human optic nerve head. Am J Ophthalmol. 1986;102:139–148. pmid:2426947
- 2. Anderson DR, Hoyt WF. Ultrastructure of intraorbital portion of human and monkey optic nerve. Arch Ophthalmol. 1969;82:506–530. pmid:4981187
- 3. Quigley HA, Addicks EM, Green WR, Maumenee AE. Optic nerve damage in human glaucoma. II. The site of injury and susceptibility to damage. Arch Ophthalmol. 1981;99:635–649. pmid:6164357
- 4. Quigley HA, Green WR. The histology of human glaucoma cupping and optic nerve damage: clinicopathologic correlation in 21 eyes. Ophthalmology. 1979;86:1803–1830. pmid:553256
- 5. Bellezza AJ, Rintalan CJ, Thompson HW, Downs JC, Hart RT, Burgoyne CF. Deformation of the lamina cribrosa and anterior scleral canal wall in early experimental glaucoma. Invest Ophthalmol Vis Sci. 2003;44:623–637. pmid:12556392
- 6. Parrish RK 2nd, Feuer WJ, Schiffman JC, Lichter PR, Musch DC. Five-year follow-up optic disc findings of the Collaborative Initial Glaucoma Treatment Study. Am J Ophthalmol. 2009;147:717–724.e711. pmid:19152871
- 7. Reis AS, O'Leary N, Stanfield MJ, Shuba LM, Nicolela MT, Chauhan BC. Laminar displacement and prelaminar tissue thickness change after glaucoma surgery imaged with optical coherence tomography. Invest Ophthalmol Vis Sci. 2012;53:5819–5826. pmid:22807291
- 8. Barrancos C, Rebolleda G, Oblanca N, Cabarga C, Muñoz-Negrete FJ. Changes in lamina cribrosa and prelaminar tissue after deep sclerectomy. Eye (Lond). 2014;28:58–65. pmid:24232316
- 9. Agoumi Y, Sharpe GP, Hutchison DM, Nicolela MT, Artes PH, Chauhan BC. Laminar and prelaminar tissue displacement during intraocular pressure elevation in glaucoma patients and healthy controls. Ophthalmology. 2011;118:52–59. pmid:20656352
- 10. Hayreh SS, Jonas JB. Optic disc morphology after arteritic anterior ischemic optic neuropathy. Ophthalmology. 2001;108:1586–1594. pmid:11535455
- 11. Henkind P, Charles NC, Pearson J. Histopathology of ischemic optic neuropathy. Am J Ophthalmol. 1970;69:78–90. pmid:4189216
- 12. Danesh-Meyer HV, Boland MV, Savino PJ, Miller NR, Subramanian PS, Girkin CA, et al. Optic disc morphology in open-angle glaucoma compared with anterior ischemic optic neuropathies. Invest Ophthalmol Vis Sci. 2010;51:2003–2010. pmid:19737875
- 13. Shields MB. Normal-tension glaucoma: is it different from primary open-angle glaucoma? Curr Opin Ophthalmol. 2008;19:85–88. pmid:18301279
- 14. Park HY, Jeon SH, Park CK. Enhanced depth imaging detects lamina cribrosa thickness differences in normal tension glaucoma and primary open-angle glaucoma. Ophthalmology. 2012;119:10–20. pmid:22015382
- 15. Lee EJ, Kim TW, Weinreb RN. Reversal of lamina cribrosa displacement and thickness after trabeculectomy in glaucoma. Ophthalmology. 2012;119:1359–1366. pmid:22464141
- 16. Hernandez MR. Ultrastructural immunocytochemical analysis of elastin in the human lamina cribrosa. Changes in elastic fibers in primary open-angle glaucoma. Invest Ophthalmol Vis Sci. 1992;33:2891–2903. pmid:1526740
- 17. Hernandez MR, Andrzejewska WM, Neufeld AH. Changes in the extracellular matrix of the human optic nerve head in primary open-angle glaucoma. Am J Ophthalmol. 1990;109:180–188. pmid:2405683
- 18. Hernandez MR, Ye H. Glaucoma: changes in extracellular matrix in the optic nerve head. Ann Med. 1993;25:309–315. pmid:8217094
- 19. Flammer J, Orgül S, Costa VP, Orzalesi N, Krieglstein GK, Serra LM, et al. The impact of ocular blood flow in glaucoma. Prog Retin Eye Res. 2002;21:359–393. pmid:12150988
- 20. Flammer J, Orgül S. Optic nerve blood-flow abnormalities in glaucoma. Prog Retin Eye Res. 1998;17:267–289. pmid:9695795
- 21. Mozaffarieh M, Flammer J. New insights in the pathogenesis and treatment of normal tension glaucoma. Curr Opin Pharmacol. 2013;13:43–49. pmid:23092679