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. 2014 Jul 4;28(9):1126–1130. doi: 10.1038/eye.2014.147

Decreased photoreceptor inner segment/outer segment junction reflectivity in patients with idiopathic epimacular membrane

I Toprak 1,*, V Yaylalı 2, C Yildirim 2
PMCID: PMC4166636  PMID: 24993328

Abstract

Purpose

To assess the effects of idiopathic epimacular membrane (IEMM) on retinal pigment epithelium (RPE), photoreceptor inner segment/outer segment (IS/OS) junction, and external limiting membrane (ELM) reflectivities to determine functional alterations in these layers using optical coherence tomography (OCT) image analysis.

Methods

Fifty eyes of 50 patients with untreated IEMM and 41 eyes of 41 age- and sex-matched healthy controls with normal OCT scans were retrospectively reviewed. A single masked physician analyzed OCT images randomly. Reflectivity values of RPE, IS/OS junction, and ELM were obtained using ‘plot profile' mode of a medical image processing computer software.

Results

The study comprised 50 patients with untreated IEMM and age- and sex-matched 41 control subjects (P>0.05). Image analysis demonstrated that IS/OS junction and ELM had significantly lower reflectivity in patients with IEMM compared with those of the control eyes (P=0.008, P=0.009, respectively). However, RPE reflectivity did not differ between two groups (P=0.100). Correlation analyses showed no significant associations between reflectivity values and corrected visual acuity (P>0.05).

Conclusion

In patients with IEMM, photoreceptor IS/OS junction and ELM seem to have lower reflectivity, which might indicate impaired functionality even though these layers are not apparently damaged on OCT imaging.

Introduction

Idiopathic epimacular membranes (IEMM) are avascular fibrocellular tissues characterized by distortion of macular surface, and history of predisposing ocular pathologies such as uveitis, retinal tear, retinal detachment, diabetic retinopathy, and retinal vascular occlusions are absent.1, 2, 3

Although pathogenesis of IEMM is still being investigated, studies have indicated that posterior vitreous detachment (PVD) has a critical role in the development of IEMM.3, 4 It was suggested that PVD causes breaks in internal limiting membrane (ILM) that lead to migration and proliferation of glial cells on retinal surface.3, 4 However, histopathologic specimens revealed complex nature of IEMM, which comprises glial cells, macrophages, retinal pigment epithelium (RPE) cells, fibrocytes, and myofibroblasts.2, 3

Clinical presentation of IEMM varies on the degree of deterioration in macular microarchitecture.5, 6 In clinical practice, dilated fundoscopic examination and optical coherence tomography (OCT) imaging are usually sufficient for the diagnosis. Furthermore, OCT allows the physician to follow-up changes in retinal microstructure, particularly integrity of photoreceptor inner segment/outer segment (IS/OS) junction, which was found associated with postoperative visual improvement.7, 8 Most of the studies concluded that an interrupted or absent IS/OS junction on OCT was significantly correlated with poor preoperative and postoperative visual acuity in patients with EMM.9, 10

In clinical practice, physicians are generally unable to detect functional loss in photoreceptors on OCT until IS/OS junction is obviously damaged. However, epimacular membrane might cause subclinical deteriorations in photoreceptor layer, and hence in IS/OS junction. In the current study, we aimed to assess the effects of IEMM on RPE, IS/OS junction, and external limiting membrane (ELM) reflectivities using a medical image processing computer software (ImageJ v. 1.47)11 to determine functional alterations in these layers, while there was no evident damage on OCT scans.

Materials and methods

Study group

Fifty eyes of 50 patients with untreated IEMM (patient group) and 41 eyes of 41 age- and sex-matched healthy subjects (control group) were included in this retrospective comparative study. Local ethics committee approved the study and tenets of the Declaration of Helsinki were followed. Inclusion criteria for the patient group were fundoscopic examination and OCT imaging consistent with IEMM. Eyes with disrupted or absent IS/OS junction on OCT images were not included into the study. Control group comprised subjects with normal ophthalmologic examination and OCT scan. Anterior segment features and intraocular pressure measurements were similar in the two groups. Patients with history of prior intraocular surgery other than uncomplicated cataract surgery, ocular trauma, inflammatory ocular diseases, retinal vascular occlusions, diabetic retinopathy, and retinal tear or detachment were excluded from the study.

Examinations

All patients underwent a complete ophthalmologic examination, including corrected distance visual acuity (CDVA) measurement with Snellen charts, slit-lamp biomicroscopic examination, applanation tonometry, and dilated fundoscopic examination (with +90 D lens). Log of the minimum angle of resolution (logMAR) equivalents were used to analyze visual acuity as offered by Holladay and Prager.12

Analysis of OCT images using ImageJ

OCT (Zeiss Cirrus HD-OCT 400; Carl Zeiss Meditec, Dublin, CA, USA) images were captured with proper quality using 6 mm × 6 mm macular cube 512 × 128 scanning mode by a single experienced technician (MA).

A total of 91 OCT images of 91 subjects (patient and control groups) and ophthalmologic examination records were retrospectively reviewed. Spectral domain OCT images were exported to ImageJ computer software.11, 13 The ImageJ is a Java-based image processing and analysis freeware developed under National Institutes of Health (NIH, Bethesda, MD, USA).11 It can calculate distances, angles, areas, intensity, and pixel value statistics on an image. This software is widely used in basic and clinical research for many years.11, 12, 13, 14 In recent years, increasing number of studies showed that ImageJ is a reliable tool and it has high inter- and intraobserver reproducibility in the field of ophthalmology.15, 16, 17

A single masked physician (IT) analyzed randomly selected OCT images using ‘plot profile' function of ImageJ (Figure 1).11, 13 A vertical straight line was drawn from vitreous cavity to choroid passing through the center of fovea (Figure 1).13 The software gave reflectivity values along this line and a reflectivity graph was created (Figure 1). In a normal OCT image, RPE layer has the highest reflectivity followed by IS/OS junction and ELM in histologic order. Based on these data, on the reflectivity graph, highest value was accepted as the reflectivity of RPE layer. Furthermore, locations of RPE layer, IS/OS junction, and ELM on OCT image were confirmed simultaneously on the reflectivity graph using ‘live' plot profile function of the software. Reflectivity values of each retinal layer were noted and converted to ‘relative reflectivity' according to the following formula.

Figure 1.

Figure 1

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Gray-scale OCT images (left) of a control subject (a) and IEMM patient (b), and peaks of RPE, photoreceptor IS/OS junction, and ELM on reflectivity graph (right) obtained from image processing program (ImageJ) are shown. ImageJ gives reflectivity values along a line (vertical white arrow) and creates reflectivity graph.

Relative reflectivity (arbitrary unit)=(reflectivity of IS/OS or ELM)/(reflectivity of RPE) × 100.

Based on the current literature, lower reflectivity was considered as functional or structural impairment in related retinal layers.18, 19

Statistical analysis

The Statistical Package for Social Sciences software version 16.0 (SPSS Inc., Chicago, IL, USA) was used for statistical analysis. Results were expressed as mean±standard deviation (SD). χ2 Test was used to compare two groups in terms of gender. Comparison of the quantitative data (age, reflectivity) between two groups was performed by independent sample t-test. Pearson's correlation coefficients were used to determine associations among visual acuity, age, and reflectivity values. A P-value <0.05 was considered statistically significant at 95% confidence interval.

Results

The study group comprised 50 eyes of 50 patients with untreated IEMM (patient group) and 41 eyes of 41 healthy subjects with normal OCT (control group). Comparing two groups, there were no significant difference in terms of age and gender (P>0.05). Table 1 shows sociodemographic characteristics of the study population. In the patient group, mean CDVA was 0.43±0.23 logMAR (20/53 Snellen equivalent).

Table 1. Demographic data of the study groups (n=91).

  Control group (n=41) Patient group (n=50) P-value
Gender     0.836a
Male, n (%) 19 (46.3%) 22 (44%)  
Female, n (%) 22 (53.7%) 28 (56%)  
       
Age (years, mean±SD) 65.3±7.1 67.0±7.7 0.312b
Male 62.9±7.0 68.0±9.4  
Female 67.5±6.7 66.2±6.1  
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Abbreviation: SD, standard deviation.

P<0.05 indicates statistical significance.

a

χ2 Test.

b

Independent sample t-test.

We retrospectively reviewed OCT data of all subjects, and image analysis was performed randomly to determine reflectivities of RPE, IS/OS junction, and ELM.

In the patient group, IS/OS junction and ELM reflectivities (absolute and relative) were significantly lower when compared with those of the control group (Table 2). However, RPE reflectivity did not show significant difference between two groups (Table 2).

Table 2. Comparison of RPE, IS/OS junction, and ELM reflectivities between the patient and control groups.

  Control group (n=41) Patient group (n=50) P-valuea
RPE reflectivity (arbitrary unit, mean±SD) 156.61±7.38 153.82±8.36 0.100
IS/OS junction reflectivity (arbitrary unit, mean±SD) 140.28±10.69 133.12±13.75 0.008
ELM reflectivity (arbitrary unit, mean±SD) 117.79±15.55 107.90±19.24 0.009
       
Relative IS/OS junction reflectivity (arbitrary unit, mean±SD) 89.59±5.67 86.55±7.78 0.040
Relative ELM reflectivity (arbitrary unit, mean±SD) 75.22±9.53 70.19±12.21 0.034
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Abbreviations: ELM, external limiting membrane; IS/OS, photoreceptor inner segment/outer segment; RPE, retina pigment epithelium; SD, standard deviation.

Bold values indicate statistical significance (P<0.05).

a

Independent sample t-test; relative reflectivity (arbitrary unit)=(reflectivity of IS/OS or ELM)/(reflectivity of RPE) × 100.

In patients with IEMM, correlation analysis revealed a significant relation between CDVA (logMAR) and age (r=0.386, P=0.009), although correlations between CDVA and reflectivity measurements were not statistically significant (P>0.05).

Discussion

IEMM is a relatively common ocular entity, and it is characterized by collagenous proliferation on inner retinal surface without a secondary cause.1, 2 Contractile nature of these membranes causes disturbance on macular microarchitecture and patients experience metamorphopsia or decrease in visual acuity.3

Since the introduction of high-resolution OCT devices, physicians have chance to obtain detailed images of retinal layers before and after treatment. In recent years, most of the studies focused on photoreceptor IS/OS junction on OCT scans and integrity of this layer was reported as a prognostic factor for postoperative visual improvement in many retinal diseases.7, 8, 9, 10, 20, 21 Michalewski et al6 sought correlations between macular morphology and visual acuity in patients with EMM using OCT. They reported that macular morphology and photoreceptor defects seemed to be prognostic factors in patients with EMM. Similarly, many studies concluded that disruption in IS/OS junction was an important predictor of poor visual outcome in eyes with IEMM.5, 10, 22, 23

In the current literature, studies identified two main pathologic patterns in IS/OS junction (disruption and absence), which were suggested to be irreversible.5, 22, 23 Thus, it can be valuable to detect subclinical deteriorations even if photoreceptor IS/OS junction appears to be intact on OCT image. In the present study, we analyzed reflectivities of RPE, IS/OS junction, and ELM on OCT scans using a medical image processing software to determine functional status of these retinal layers in patients with IEMM. We found significant decreases in IS/OS junction and ELM reflectivities (both absolute and relative) compared with those of the healthy eyes, whereas RPE reflectivity did not show a significant difference between the patient and control groups. In a healthy macula, IS/OS junction can be seen as a continuous hyper-reflective band on OCT image, and recent studies demonstrated that decreased reflectivity of this layer is associated with diminished photoreceptor function.18, 19 Based on this knowledge, loss of reflectivity in IS/OS junction and ELM might indicate that EMM leads to subclinical functional or structural impairment in these layers. However, correlation analysis did not show a significant association between reflectivity values and CDVA.

In patients with IEMM, clinical symptoms vary on distortionary effect of membrane on macular microstructure. Although recent studies agreed that disrupted or absent IS/OS junction on OCT scan (which could be irreversible) was an important predictor of poor visual acuity.9, 10, 22, 23 Early effects of IEMM on functions of retinal layers were not reported previously to the best of our knowledge.

In conclusion, our study revealed that IEMM might lead to subclinical deteriorations in IS/OS junction and ELM even though patient has a continuous IS/OS junction and ELM on OCT scan.

graphic file with name eye2014147i1.jpg

Acknowledgments

This study was performed in adherence to the tenets of the Declaration of Helsinki and Local Ethics Committee approved the study.

The authors declare no conflict of interest.

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