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Klinika Oczna / Acta Ophthalmologica Polonica
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Color vision impairment in multiple sclerosis and neuromyelitis optica spectrum disorder

Małgorzata Rogaczewska
1
,
Sławomir Michalak
2
,
Marcin Stopa
1

  1. Department of Ophthalmology, Chair of Ophthalmology and Optometry, Poznan University of Medical Sciences, Poznan, Poland
  2. Department of Neurochemistry and Neuropathology, Chair of Neurology, Poznan University of Medical Sciences, Poznan, Poland
KLINIKA OCZNA 2021, 123, 2:96–101
Data publikacji online: 2021/07/14
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INTRODUCTION

Multiple sclerosis (MS) and neuromyelitis optica spectrum disorder (NMOSD) are inflammatory demyelinating conditions of the central nervous system [1, 2]. Neuromyelitis optica spectrum disorder was considered a variant of MS until 2004, when the disease-specific serum IgG was discovered [3]. This antibody, which binds to the aquaporin-4 (AQP4) water channel presented in the membrane of astrocytes and Müller cells, can be detected in up to 80% of NMOSD patients [4, 5]. Multiple sclerosis and NMOSD patients had the color vision independently assessed with a variety of tests, inter alia, Ishihara plates, Hardy-Rand-Rittler (HRR) plates, Farnsworth Panel D-15, and the Farnsworth-Munsell 100 (FM-100) hue test [6-19]. Although time-consuming, the FM-100 hue test is considered the most useful in evaluating the acquired color defects by providing the severity and the type of dyschromatopsia [20]. Optic neuritis (ON) is a common manifestation of both diseases, yet in NMOSD patients, the inflammation has a more severe course with a poorer visual outcome [21]. Regarding ON and non-ON eyes, the color vision abnormalities in MS and NMOSD patients were comparatively evaluated only in one study by Merle et al. [22]. They reported that the severity of dyschromatopsia did not differ between MS and NMOSD. However, the type of color defect was not defined [22].
Several authors have investigated the association between color vision impairment and retinal nerve fiber layer (RNFL) and ganglion cell complex (GCC) thickness acquired with optical coherence tomography (OCT). In MS patients, the results were not consistent depending on the used test (HRR, Farnsworth Panel D-15, or FM-100), whereas in NMOSD patients, no correlation was found [7-13, 18, 19, 23]. This study aimed to identify color vision abnormalities with the FM-100 hue test in MS and NMOSD patients, considering ON and non-ON eyes. Furthermore, we evaluated the relationship between the severity of dyschromatopsia and retinal neurovascular parameters obtained with spectral-domain OCT (SD-OCT) and OCT angiography (OCTA).

MATERIAL AND METHODS

Ethical approval

The study was performed in accordance with the Declaration of Helsinki and was approved by the medical ethics committee of Poznan University of Medical Sciences (approval no. 562/18 from May 2018). Written informed consent was obtained from all participants after a full explanation of the study.

Study participants

This single-center study was conducted at the Department of Ophthalmology and the Department of Neurology of Poznan University of Medical Sciences between June 2018 and September 2020. We recruited relapsing-remitting MS and AQP4-IgG seropositive NMOSD patients, as well as age- and sex-matched healthy controls. Multiple sclerosis and NMOSD were diagnosed according to the 2017 McDonald criteria and 2015 International Panel for NMO Diagnosis criteria, respectively [24, 25]. The AQP4-IgG was detected by a commercial cell-based indirect immunofluorescence assay (EUROIMMUN AG, Lübeck, Germany). Analyses were performed in the Department of Neurochemistry and Neuropathology at Poznan University of Medical Sciences, which participates in an international external quality control system and receives regular certification for the detection of AQP4-IgG (Institut für Qualitätssicherung, Lübeck, Germany). Although, in total, 24 NMOSD patients were diagnosed with AQP4-IgG seropositive disease in our institution, only 13 patients were enrolled in this study. Seven patients could not undergo ophthalmic examination because of visual or physical disability, and four patients refused to participate. Clinical data, including the history of ON and disease duration, were collected. We classified MS and NMOSD patients’ eyes based on the presence (MS+ON, NMOSD+ON) or absence (MS-ON, NMOSD-ON) of a previous ON episode. The inclusion criteria were age ≥ 18 years, no ON attack within the last 6 months before the examination, and at least 2 years of disease duration for MS patients. The exclusion criteria were myopia greater than 6 diopters, congenital dyschromatopsia, glaucoma, optic disc drusen, macular disease, hypertensive or diabetic retinopathy, history of uveitis, previous eye surgery, and low OCT image quality.

Basic ophthalmic examination

All participants underwent best-corrected visual acuity (BCVA) testing, slit-lamp biomicroscopy, indirect ophthalmoscopy, and Goldmann applanation tonometry with central corneal thickness correction. BCVA was assessed with the Early Treatment of Diabetic Retinopathy Study chart and expressed as a logarithm of the minimum angle of resolution (logMAR).

Color vision assessment

Color discrimination ability was evaluated by the FM-100 hue test (Farnsworth 100 Hue Test, Richmond Products Inc., Albuquerque, NM, USA) and carried out in a dark room under daylight illumination with a color temperature of 6280 kelvin (Daylight Illuminator, Good-Lite, Elgin, Il, USA). The test consists of 85 color caps that form a color circle and are stored in four boxes. Patients were asked to arrange the previously mixed-up caps in order according to hue between two fixed end caps in each box, with no time limit. Both eyes of the participants were tested monocularly, with the non-tested eye occluded. For each cap, an error score was calculated as the sum of the differences between the number of that cap and the numbers of the two caps adjacent on each side. The total error score (TES) was computed as the sum of the error scores for each of the 85 caps. Additionally, we calculated the total partial error score (TPES) for the blue-yellow (B-Y) and red-green (R-G) axes according to the method of Smith et al. [26]. As recommended, to reach the normal distribution of error scores for statistical analysis, the square root transformation of TES (√TES) and TPES (√TPES) was applied [27].

OCT data acquisition

The SD-OCT and OCTA images were obtained with RTVue XR Avanti with AngioVue (Optovue Inc., Fremont, CA, USA; software version 2017.1.0.151). The RNFL thickness was evaluated using the optic nerve head map protocol and measured at a diameter of 3.45 mm around the center of the optic disc. The GCC scan (7 x 7 mm square grid) was centered 1 mm temporal to the fovea, and the GCC thickness was automatically measured from the internal limiting membrane (ILM) to the outer boundary of the inner plexiform layer (IPL). The AngioVue imaging system was based on a split-spectrum amplitude-decorrelation angiography algorithm that detects the blood motion in the vessels through sequentially obtained OCT cross-sectional scans. The blood flow maps presented the vessel density, i.e., the percentage area occupied by the perfused retinal blood vessels in the analyzed region [28, 29]. The parafoveal retinal capillaries were visualized using a 3 × 3 mm scan centered on the fovea and divided into plexuses by the AngioVue software. The superficial capillary plexus (SCP) was segmented from the ILM to 9 μm above the IPL, and the deep capillary plexus (DCP) was segmented from 9 μm above the IPL to 9 μm below the outer plexiform layer. The parafovea was defined as an annulus with an inner and outer diameter of 1.0 mm and 3.0 mm, respectively. The radial peripapillary capillary (RPC) plexus was acquired using 4.5 × 4.5 mm rectangle scan centered on the optic nerve head. The capillaries within the ILM and the nerve fiber layer’s outer boundary were analyzed in the peripapillary area defined as a 1.0-mm wide round annulus extending outward from the optic disc boundary. Low-quality OCT images, i.e., with the signal strength index < 50 or significant motion artifacts, were not analyzed. The OCT data were reported in alignment with APOSTEL recommendations [30].

Statistical analysis

Statistical analysis was performed using Statistica v13.3 (StatSoft, Inc., Tulsa, OK, USA) and SPSS (SPSS, Inc., Chicago, IL, USA). The Shapiro-Wilk test was used to determine the distribution of continuous variables. The differences between two unpaired groups were assessed using Student’s t-test and the Mann-Whitney U-test, whereas the Chi-square test and Kruskal-Wallis test were used to evaluate the differences among several unpaired groups. We performed generalized estimating equation models accounting for intrasubject inter-eye dependencies to compare the color vision error score between cohorts. Pearson’s or Spearman’s correlations were calculated between √TES and selected variables. Due to the exploratory nature of this study, no correction for multiple comparisons was made. Statistical significance was set at p < 0.05.

RESULTS

Study population

In total, 40 MS patients, 13 NMOSD patients, and 20 healthy controls were enrolled. We evaluated eyes with the complete OCT data; therefore, seven eyes of MS patients and nine eyes of NMOSD patients were excluded. There was no difference between the groups regarding age, sex, and disease duration except for BCVA of enrolled eyes (p = 0.014). Demographic and clinical features are summarized in Table I.

Color vision

The √TES, as well as B-Y and R-G √TPES, were significantly higher in MS+ON, MS-ON, NMOSD+ON, and NMOSD-ON than in the control group (Tables II and III, Figure 1). Comparing ON and non-ON eyes, the color vision did not differ in MS eyes, whereas in NMOSD, the √TES and √TPES were significantly higher in ON eyes (Table III). The color vision was significantly more impaired in NMOSD+ON than MS+ON eyes, while between NMOSD-ON and MS-ON groups, the error scores were comparable (Table III). Within the groups, the severity of dyschromatopsia did not differ between the B-Y and R-G axes (Figure 1). The type of color vision defects was identified as follows: tritan in MS+ON (n = 2) and NMOSD+ON (n = 1) eyes, and protan in one MS-ON eye. The remaining eyes presented mixed color defects.

Correlation between √TES and clinical data

A significant positive moderate correlation was found between √TES and age in MS+ON, MS-ON, and control groups (Table IV). No significant correlation between √TES and age was observed in NMOSD+ON (r = –0.467, p = 0.243) and NMOSD-ON (r = –0.302, p = 0.429; Table IV). An association between √TES and disease duration was found in MS+ON and MS-ON eyes only (Table IV).

Correlation between √TES and OCT parameters

The baseline SD-OCT and OCTA measurements are presented in Table II. The √TES strongly negatively correlated with GCC thickness in NMOSD-ON eyes (r = –0.738, p = 0.023), whereas in other groups, this relationship was insignificant (Table IV). An association between √TES and the vessel density of SCP and RPC was only found in MS+ON eyes (r = –0.518, p = 0.003; r = –0.413, p = 0.023, respectively; Table IV). The √TES did not correlate with RNFL thickness or the vessel density of DCP in any group (Table IV).

DISCUSSION

In this study, we found color vision impairment in MS and NMOSD patients in both ON and non-ON eyes. Moreover, the in-depth analysis revealed no specific color vision pattern in those eyes. There are only a few studies where the color vision was assessed with the FM-100 hue test in MS and NMOSD patients [15-19, 22, 23]. In two of them, the authors did not present the color vision abnormalities strictly associated with ON, because the ON and non-ON eyes were reported as one group [18, 23]. Two other studies evaluated only MS-ON eyes, and the results were inconsistent [17, 19]. However, Fleishman et al. found that MS+ON and MS-ON groups had significantly higher TES than healthy controls, which was in agreement with our findings [15]. So far, little is known about the color vision defects in NMOSD. No study has examined the effect of optic neuritis on color discrimination ability in those patients. Our analysis showed that ON and non-ON eyes had higher error scores in NMOSD patients than the control group.
Comparing the severity of TPES, we found the errors evenly distributed between B-Y and R-G axes in MS and NMOSD groups. Additionally, the tritan and protan axis of confusion was observed only in three eyes (two MS+ON, one NMOSD+ON) and in one eye (one MS-ON), respectively. In 1995, Katz reported that no single type of dyschromatopsia occurred in MS+ON eyes [16]. Two recent studies employing Farnsworth Panel D-15 provided similar results, i.e., the mixed color deficiency was present in MS-ON and NMOSD-ON groups [13, 14]. Consequently, our finding of no specific confusion axis was in line with the previous reports. Our study showed that TES and TPES did not differ between MS+ON and MS-ON eyes, whereas the color vision in NMOSD+ON was significantly more impaired than in NMOSD-ON and MS+ON eyes. We suppose that the comparable results between MS groups may be related to the progressive neurodegeneration process, which is ON-independent and more pronounced in MS than in NMOSD [31]. In NMOSD, the inflammation of the optic nerve is more severe than in MS [21]. Thus, it may explain more significant color vision defects in NMOSD+ON compared with both NMOSD-ON and MS+ON. As mentioned above, MS and NMOSD eyes have been collectively evaluated only in one study [22]. Merle et al. found no difference between either MS+ON and NMOSD+ON or MS-ON and NMOSD-ON groups [22]. Likewise, in our study, the severity of color vision defects was similar between MS-ON and NMOSD-ON eyes.
It is known that in adults, the color discrimination ability deteriorates with age [32]. Such a relationship can be observed in our healthy controls. In both MS groups, we also noted a moderate positive correlation between TES and age, whereas in NMOSD+ON and NMOSD-ON the relationship was negative but not significant. According to disease duration, a moderate positive association with TES was observed in MS groups. These findings suggest that in NMOSD patients, severe color vision impairment may appear at a younger age or earlier in the disease course.
The link between color vision defects and retinal neuronal and axonal loss in MS has been a subject of several studies; however, only non-ON eyes were investigated [8, 9, 13, 19]. Depending on the used test, the GCC and RNFL thickness correlated with color vision outcome (HRR, Farnsworth Panel D-15) or not (FM-100) [8, 9, 13, 19]. Lampert et al. reported that HRR scores were strongly related to retinal ganglion cell injury in MS-ON eyes [9]. They also suggested that dyschromatopsia might serve as an accurate marker of retinal damage [9]. In fact, not every test is appropriate to be used in detailed analysis. The HRR test was designed for screening purposes, and, together with the Farnsworth Panel D-15, did not provide the precise assessment of color vision as did the FM-100 hue test [20]. In our study, the correlation between TES and GCC thickness was observed only in NMOSD-ON eyes, and RNFL thickness was not associated with TES in any group. Interestingly, we noted an association between color vision and vessel density of SCP and RPC in the MS+ON group. In NMOSD+ON, a similar moderate trend was found regarding SCP. We did not find any study showing such a relation; thus, we cannot clearly state whether this is an incidental or significant finding. Our study has several limitations. The group of NMOSD patients was relatively small due to the low prevalence of the disease. We evaluated only AQP4-IgG seropositive NMOSD patients. Therefore, the results may not extend to seronegative NMOSD. Because this was a single-center study, further investigations with different populations are necessary to confirm our observations.
In conclusion, our study revealed color vision impairment in MS and NMOSD patients, regardless of optic neuritis history. Moreover, no predilection towards the B-Y or R-G axis was found in those groups. Our results show that dyschromatopsia was not associated with retinal ganglion cells and axonal damage.

ACKNOWLEDGEMENTS

We would like to thank Ass. Prof. Alicja Kalinowska-Łyszczarz and Dr. Michalina Jasiak-Zatońska for their assistance in patients’ recruitment.

DISCLOSURE

The authors declare no conflict of interest.

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