Figures
Abstract
Purpose
To assess a potential role of Bruch´s membrane (BM) in the biomechanics of the eye, we measured its thickness and the density of retinal pigment epithelium (RPE) cells in various ocular regions in eyes of varying axial length.
Methods
Human globes, enucleated because of an ocular tumor or end-stage glaucoma were prepared for histological examination. Using light microscopy, the histological slides were histomorphometrically examined applying a digitized image analysis system.
Results
The study included 104 eyes with a mean axial length of 27.9±3.2 mm (range:22.6mm-36.5mm). In eyes without congenital glaucoma, BM was significantly thickest (P<0.001) at the ora serrata, followed by the posterior pole, the midpoint between equator and posterior pole (MBEPP), and finally the equator. BM thickness was not significantly correlated with axial length (ora serrata: P = 0.93; equator:P = 0.31; MBEPP:P = 0.15; posterior pole:P = 0.35). RPE cell density in the pre-equatorial region (P = 0.02; regression coefficient r = -0.24) and in the retro-equatorial region (P = 0.03; r = -0.22) decreased with longer axial length, while RPE cell density at the ora serrata (P = 0.35), the MBEPP (P = 0.06; r = -0.19) and the posterior pole (P = 0.38) was not significantly correlated with axial length. Highly myopic eyes with congenital glaucoma showed a tendency towards lower BM thickness and lower RPE cell density at all locations.
Conclusions
BM thickness, in contrast to scleral and choroidal thickness, was independent of axial length in eyes without congenital glaucoma. In association with an axial elongation associated decrease in the RPE cell density in the midperiphery, the findings support the notion of a biomechanical role BM may play in the process of emmetropization/myopization.
Citation: Bai HX, Mao Y, Shen L, Xu XL, Gao F, Zhang ZB, et al. (2017) Bruch´s membrane thickness in relationship to axial length. PLoS ONE 12(8): e0182080. https://doi.org/10.1371/journal.pone.0182080
Editor: James Fielding Hejtmancik, National Eye Institute, UNITED STATES
Received: May 5, 2017; Accepted: July 10, 2017; Published: August 2, 2017
Copyright: © 2017 Bai 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 and its Supporting Information file.
Funding: The authors received no specific funding for this work.
Competing interests: I have read the journal's policy and the authors of this manuscript have the following competing interests: Jost B. Jonas: Consultant for Mundipharma Co. (Cambridge, UK); Patent holder with Biocompatibles UK Ltd. (Franham, Surrey, UK) (Title: Treatment of eye diseases using encapsulated cells encoding and secreting neuroprotective factor and/or anti-angiogenic factor; Patent number: 20120263794), and Patent application with University of Heidelberg (Heidelberg, Germany) (Title: Agents for use in the therapeutic or prophylactic treatment of myopia or hyperopia; European Patent Number: 3 070 101). This does not alter our adherence to PLOS ONE policies on sharing data and materials.
Introduction
Bruch´s membrane (BM) forms the border between the intravitreal cavity with the vitreous body and retina on its inner side and the choroid on its outer side [1]. It is formed by the retinal pigment epithelium (RPE) and consists of the basal membrane of the latter, two collagenous layers separated from each other by an elastic layer in its center, and the basal membrane of the choriocapillaris on its outer side. Together with the RPE, BM participates in forming the blood retina barrier, separating the retina with its almost fluid-free interstitial space from the spongy choroid with fenestrated choriocapillaris vessel walls and pronounced interstitial fluid. Recent studies on the emmetropization of the eye have suggested that BM, in addition to having a function in separating the retinal and vitreal compartment from the choroidal space, could play a biomechanical role in the process of emmetropization and myopization [2–9]. Since the biomechanical characteristics of a tissue strongly depend on its thickness, we measured the thickness of BM in different locations of human enucleated eyes. We also assessed the density of the RPE cells since the latter produce the BM.
Methods
The histomorphometric investigation included human globes which had been enucleated due to uveal melanomas or end-stage painful glaucoma. The Medical Ethics Committee of the Beijing Tongren Hospital approved the study protocol according to the Declaration of Helsinki. The necessity of a written informed consent by the patients was waived since the eyes had been enucleated up to 50 years before the study was started. As inclusion criterion, all histological slides examined in the study had to run through the center of the cornea, the optic disc and through the posterior pole. Exclusion criteria were tissue changes attributable to the underlying diseases and which prevented a thickness measurement of BM.
After processing the enucleated eyes were prepared in a standardized manner for light microscopical examination. It included fixation in a solution of 4% formaldehyde for at least 24 hours, measurement of the sagittal globe diameter, sectioning of the eyes, and staining of the slides with hematoxycilin eosin or by the Periodic-Acid-Shiff (PAS) method. The slides were histomorphometrically examined using a digitized image analysis system (Moticam 2006 (2.0M pixel USB2.0) and Motic Digital Medical Image Analysis System, Motic China group, Co. Ltd. Xiamen, China). We measured the thickness of BM (defined as the distance between the basal membrane of the RPE on its inner side to the basal membrane of the choriocapillaris on its outer side), the thickness of the choroid and the thickness of the sclera at the ora serrata, the equator, the midpoint between the equator and the posterior pole (MBEPP), and at the posterior pole (Fig 1). Scleral thickness was additionally determined in the pars plana region. At each measurement region, four measurements at slightly different points were obtained and the mean of these measurements was taken for further statistical analysis. For the assessment of the density of the RPE cells, we used the same digitized image analysis system, and we counted the number of RPE cells on Bruch´s membrane for a length of 480 μm in the region just posterior to the ora serrata, the region just anterior to the equator, the region just posterior to the equator, at the MBEPP, and at the posterior pole. The methods have been described in detail recently [4–8,10].
A statistical analysis program (SPSS, version 22.0, IBM-SPSS, Chicago, IL, USA) was used for the statistical analysis. In a first step, we calculated the mean values ± standard deviations of the outcome parameters at each measurement location. Using a two-tailed student-t-test for paired samples, we then compared in a second step the BM thickness measurements and RPE density values between the various locations of measurement. Finally, in linear regression analysis, we performed a univariate analysis, followed by a multivariate analysis, to test associations between BM thickness or the RPE cell count with axial length and other parameters. All P-values were 2-sided and considered statistically significant when less than 0.05.
Results
The study included 104 globes of 104 patients (51 women) with a mean age of 35.7 ± 18.4 years (median: 35 years; range:1–81 years) and a mean axial length of 27.9 ± 3.2 mm (median: 27.5 mm; range: 22.6mm–36.5mm). Reasons for enucleation were uveal melanoma in 34 patients and end-stage painful glaucoma in 70 patients, among them five patients with congenital glaucoma. Axial length was longer than 26.0 mm in 64 eyes.
In the eyes without congenital glaucoma, BM thickness was significantly the thickest (P<0.001) at the ora serrata, followed by the posterior pole, the MBEPP, and the equator (Table 1) (Fig 2). In the eyes without congenital glaucoma, BM thickness was not significantly correlated with axial length, neither at the ora serrata (P = 0.93), the equator (P = 0.31), the MBEPP (P = 0.15) nor the posterior pole (P = 0.35) (Fig 3). Correspondingly, the non-highly myopic group and the highly myopic group without congenital glaucoma did not differ significantly (P>0.15) in BM thickness (Table 1). BM thickness showed a tendency towards thinner measurements in the group of eyes with secondary high myopia due to congenital glaucoma as compared to both other groups (Table 1). The differences were however not statistically significant.
BM thickness increased significantly with older age when measured at the ora serrata (P = 0.01; r = 0.25) and at the equator (P<0.001; r = 0.43), while BM thickness measured at the MBEPP (P = 0.20) or at the posterior pole (P = 0.17) was not significantly associated with age (Fig 4).
BM thickness measurements obtained at any location did not differ between the glaucomatous group and the non-glaucomatous group (P>0.30).
In the eyes without congenital glaucoma, RPE cell density measured in the pre-equatorial region (P = 0.02; regression coefficient r = -0.24) and in the retro-equatorial region (P = 0.03; r = -0.22) decreased with longer axial length, while RPE cell density in the ora serrata region (P = 0.35), at the MBEPP (P = 0.06; r = -0.19) and at the posterior pole (P = 0.38) was not significantly correlated with axial length (Figs 5 and 6). RPE density at the posterior pole showed a tendency to be lower in the eyes with secondary high myopia due to congenital glaucoma (24.8 ± 3.3 cells / 480μm section length) than in the eyes with primary high myopia (27.0 ± 3.5 cells / 480μm section length) and the non-highly myopic eyes (27.0 ± 3.0 cells / 480μm section length) (Table 1) (Fig 6). The differences were however not statistically significant (P = 0.20).
The thickness of the choroid decreased significantly with longer axial length for choroidal thickness measurements obtained at the equator (P = 0.006; r = -0.27), at the MBEPP (P<0.001; r = -0.35) and at the posterior pole (P<0.001; r = -0.39). The association was most marked for the choroidal measurements taken at the posterior pole. There was no difference if the highly myopic eyes with congenital glaucoma were included or excluded from the analysis. Scleral thickness measured at the ora serrata (P<0.001; r = -0.51), the equator (P<0.001; r = -0.13), the MBEPP (P = 0.02; r = -0.23) and at the posterior pole (P<0.001; r = -0.60) decreased with longer axial length, most marked at the posterior pole (Fig 7). Again, there was no difference if the highly myopic eyes with congenital glaucoma were included or excluded from the analysis.
Discussion
In this histomorphometric study on human eyes, the thickness of BM was not related with axial length in eyes without congenital glaucoma. The density of the RPE cells decreased with longer axial length in the pre-equatorial and retro-equatorial region, while at the posterior pole, as was the thickness of BM, the RPE cell density was not significantly correlated with axial length. In contrast, thickness of choroid and of the sclera markedly decreased with longer axial length, most marked at the posterior pole.
These findings obtained on Chinese eyes confirmed the results of a previous investigation on Western European eyes, in which as in the present study, BM thickness was not related with axial length in eyes without congenital glaucoma, and in which the RPE cell density decreased in the retro-equatorial region with elongating axial length [8,10]. In eyes with congenital glaucoma examined previously, BM thickness showed a marginally significant inverse association with axial length, while the present study only showed a tendency towards a thinner BM in the highly myopic eyes with congenital glaucoma [6].
The findings obtained in the present study and in the previous investigation on different study populations cannot fully be compared with results obtained in other studies, since BM thickness has not intensively been examined yet, except for in a relatively few studies on BM thickness in relation to age-related macular degeneration [11–17]. In all these latter studies, BM thickness was not compared with axial length.
The BM thickness measurements obtained in the present study were thinner than in the previous study in which BM thickness was measured with the help of a millimeter scale aligned with the ocular of the light microscope [10]. The values of the present study were also slightly thinner than the measurements of BM thickness Ramrattan and colleagues obtained with values ranging between 2 and 5 μm [13]. Reason for the discrepancy between both studies might have been that Ramrattan´s study in contrast to our investigation also included eyes with age-related macular degeneration.
The finding that BM thickness, in contrast to choroidal thickness and scleral thickness, did not decrease with increasing axial length fitted with the hypothesis that BM might play a role in the process of emmetropization [2]. The latter, taking place after the end of the second year of life, has been defined as the adjustment of the length of the optical axis in relationship to the refractive power of cornea and lens. The hypothesis was based on findings that after a spherical eye growth with active increase in scleral volume till the end of the second year of life, the dimensions of cornea and lens remain mostly constant while the globe elongates axially to bring the foveola into the optical focus. That axial elongation was accompanied by a thinning of the choroid and sclera, leading to a re-arrangement of the available choroidal and scleral tissue without a major active increase in tissue volume [4,18,19]. Thinning of the choroid and sclera was most marked at the posterior pole. In contrast to the choroidal and scleral thinning, retinal thickness in the macular region did not decrease with longer axial length, parallel to the observation that best corrected visual acuity was independent of axial length if eyes with myopic maculopathy were excluded [7,20]. There was however a thinning of the retina in the midperiphery collateral to a decrease in the density of the RPE cells in the same region, as has also been found in the present study [7,8]. Other studies had suggested that the detection of a defocus of the image on the retina is perceived in the retro-equatorial region [21–24]. Since BM thickness was independent of axial elongation as found in the present study and the previous investigation on an ethnically different study population, it has been postulated that axial elongation occurred by a production of new BM in the retro-equatorial region. It could explain the axial elongation-associated thinning of the retina and decrease in the density of the RPE cells in that region. It could also explain that the length of BM in the macular region, the density of the RPE cells at the posterior pole (as also shown in the present study), the macular retinal thickness, and correspondingly, best corrected visual acuity, were independent of axial length. The axial elongation-related increase in the optic disc-fovea distance occurred by the development and enlargement of parapapillary gamma zone without BM [25]. Fitting with the hypothesis of BM playing a role in axial elongation, a recent experimental study on guinea pigs with lens-induced myopization showed that an intravitreally applied antibody of amphiregulin was associated with a dosage-dependent decrease in axial elongation [9]. Amphiregulin is a member of the epithelial growth factor family, and the RPE has receptors for epidermal growth factor and amphiregulin [9,26].
If the results of the present study are discussed, potential limitations should be taken into account. First, the measurements were influenced by the post mortem tissue swelling and fixation induced tissue shrinkage. Since BM does not contain blood vessels and may not show a marked edema, it might have been unlikely however, that preparation-associated tissue changes had markedly changed BM thickness. Second, the study material consisted of sagittal sections through the pupil and the optic nerve, while serial sections of the eyes were not available. Third, the investigation consisted of eyes with tumors or end-stage glaucoma so that it has remained unclear whether the results can be transferred onto normal human eyes. Fourth, the group of eyes with congenital glaucoma was rather small with 5 globes included, so that the statistical power for analysis of the data of these eyes was limited.
In conclusion, BM thickness, in contrast to scleral and choroidal thickness was independent of axial length in eyes without congenital glaucoma. In association with an axial elongation associated decrease in the RPE cell density in the midperiphery, the findings support the notion of a biomechanical role BM may play in the process of emmetropization/myopization.
Supporting information
S1 Datafile. S1 datafile containing microdata of the study.
https://doi.org/10.1371/journal.pone.0182080.s001
(SAV)
References
- 1.
Curcio CA, Johnson M. Structure, function and pathology of Bruch´s membrane. In: Ryan SJ, Schachat AP, Wilkinson CP, Hinton DR, Sadda SR, Wiedemann P. Retina 5th edition. Saunders Co., 2012; Chapter 20.
- 2. Jonas JB, Ohno-Matsui K, Jiang WJ, Panda-Jonas S. Bruch´s membrane and the mechanism of myopization. A new theory. Retina. 2017 Jan 12. [Epub ahead of print]. pmid:28085774
- 3. Jonas JB, Wang YX, Zhang Q, Liu Y, Xu L, Wei WB. Macular Bruch´s membrane length and axial length. The Beijing Eye Study. PloS One 2015;10:e0136833. pmid:26317992
- 4. Shen L, You QS, Xu X, Gao F, Zhang Z, Li B, et al. Scleral and choroidal volume in relation to axial length in infants with retinoblastoma versus adults with malignant melanomas or end-stage glaucoma. Graefes Arch Clin Exp Ophthalmol 2016;254:1779–1786. pmid:27116210
- 5. Shen L, You QS, Xu X, Gao F, Zhang Z, Li B, et al. Scleral and choroidal thickness in secondary high axial myopia. Retina 2016;36:1579–1585. pmid:26735565
- 6. Jonas JB, Holbach L, Panda-Jonas S. Histologic differences between primary high myopia and secondary high myopia due to congenital glaucoma. Acta Ophthalmol 2016;94:147–153. pmid:26695106
- 7. Jonas JB, Xu L, Wei WB, Pan Z, Yang H, Holbach L, et al. Retinal thickness and axial length. Invest Ophthalmol Vis Sci 2016;57:1791–1797. pmid:27074383
- 8. Jonas JB, Ohno-Matsui K, Holbach L, Panda-Jonas S. Retinal pigment epithelium cell density in relationship to axial length in human eyes. Acta Ophthalmol 2017;95:e22–e28. pmid:27545271
- 9. Jiang WJ, Song HX, Li SY, Guo B, Wu JF, Li GP, et al. Amphiregulin antibody and reduction of axial elongation in experimental myopia. EBioMedicine 2017;17:134–144. pmid:28256400
- 10. Jonas JB, Holbach L, Panda-Jonas S. Bruch´s membrane thickness in high myopia. Acta Ophthalmol 2014;92:e470–474. pmid:24612938
- 11. Newsome DA, Huh W, Green WR. Bruch's membrane age-related changes vary by region. Curr Eye Res 1987;6:1211–1221. pmid:3677781
- 12. Pauleikhoff D, Harper CA, Marshall J, Bird AC. Aging changes in Bruch’s membrane: a histochemical and morphological study. Ophthalmology 1990;97:171–178. pmid:1691475
- 13. Ramrattan RS, van der Schaft TL, Mooy CM, de Bruijn WC, Mulder PG, de Jong PT. Morphometric analysis of Bruch’s membrane, the choriocapillaris, and the choroid in aging. Invest Ophthalmol Vis Sci 1994;35:2857–2864. pmid:8188481
- 14. Guymer R, Luthert P, Bird A. Changes in Bruch's membrane and related structures with age. Prog Retin Eye Res 1999;18:59–90. pmid:9920499
- 15. Okubo A, Rosa RH Jr, Bunce CV, Alexander RA, Fan JT, Bird AC, et al. The relationships of age changes in retinal pigment epithelium and Bruch's membrane. Invest Ophthalmol Vis Sci 1999;40:443–449. pmid:9950604
- 16. Dithmar S, Curcio CA, Le NA, Brown S, Grossniklaus HE, et al. Ultrastructural changes in Bruch's membrane of apolipoprotein E-deficient mice. Invest Ophthalmol Vis Sci 2000;41:2035–2042. pmid:10892840
- 17. Chong NH, Keonin J, Luthert PJ, Frennesson CI, Weingeist DM, Wolf RL, et al. Decreased thickness and integrity of the macular elastic layer of Bruch's membrane correspond to the distribution of lesions associated with age-related macular degeneration. Am J Pathol 2005;166:241–251. pmid:15632016
- 18. Heine L. Beiträge zur Anatomie des myopischen Auges. Arch Augenheilk 1899;38:277–290.
- 19. Vurgese S, Panda-Jonas S, Jonas JB. Sclera thickness in human globes and its relations to age, axial length and glaucoma. PLoS One 2012;7:e29692.
- 20. Shao L, Xu L, Wei WB, Chen CX, Du KF, Li XP, et al. Visual acuity and subfoveal choroidal thickness. The Beijing Eye Study. Am J Ophthalmol 2014;158:702–709.e1 pmid:24878308
- 21. Benavente-Pérez A, Nour A, Troilo D. Axial eye growth and refractive error development can be modified by exposing the peripheral retina to relative myopic or hyperopic defocus. Invest Ophthalmol Vis Sci 2014;55:6765–6773. pmid:25190657
- 22. Berntsen DA, Barr CD, Mutti DO, Zadnik K. Peripheral defocus and myopia progression in myopic children randomly assigned to wear single vision and progressive addition lenses. Invest Ophthalmol Vis Sci 2013;54:5761–5770. pmid:23838771
- 23. Hasebe S, Jun J, Varnas SR. Myopia control with positively aspherized progressive addition lenses: a 2-year, multicenter, randomized, controlled trial. Invest Ophthalmol Vis Sci 2014;55: 7177–7788. pmid:25270192
- 24. Smith EL 3rd, Hung LF, Huang J, Blasdel TL, Humbird TL, Bockhorst KH. Effects of optical defocus on refractive development in monkeys: evidence for local, regionally selective mechanisms. Invest Ophthalmol Vis Sci 2010;51:3864–3873. pmid:20220051
- 25. Jonas RA, Wang YX, Yang H, Li JJ, Xu L, Panda-Jonas S, et al. Optic disc—fovea distance, axial length and parapapillary zones. The Beijing Eye Study 2011. PloS One 2015;10:e0138701. pmid:26390438
- 26. Yan F, Hui YN, Li YJ, Guo CM, Meng H. Epidermal growth factor receptor in cultured human retinal pigment epithelial cells. Ophthalmologica 2007;221:244–250. pmid:17579290