Transcutaneous Electrical Retinal Stimulation Therapy for Age-Related Macular Degeneration

Abstract

This reports the preliminary outcome of a transpalpebral electrical retinal stimulation therapy for age-related macular degeneration (ARMD).

Twenty-one patients consisting of 16 with wet-type (Group-W) and 5 with dry-type (Group-D) ARMD with a mean age of 73.9 ± 9.5 years (range 51 to 85 years) were recruited for this study. Transpalpebral electrical retinal stimulation (20 minutes, 800 μA) was applied on the patients 4 times per day for up to 1 month. The mean best-corrected visual acuity (Early Treatment Diabetic Retinopathy Study [ETDRS] score) changed from 29.5±5.1 to 31.8±5.0 in Group-W and from 39.8±4.7 to 42.9±4.9 in Group-D. Neither ocular nor systemic adverse effects were observed with the exception of one patient who developed contact dermatitis. Due to several limitations such as lack of control, patients’ learning effect, etc, the efficacy of the therapy could not be drawn. This preliminary study, however, showed that the transpalpebral electrical retinal stimulation therapy can be non-invasively applied on wet-type ARMD patients.

INTRODUCTION

Age-related macular degeneration (ARMD) is a leading cause of blindness in industrialized countries, which affects primarily the choriocapillaris, Bruch’s membrane, and the retinal pigment epithelium [1].

The exudative form, so-called wet type, is characterized by the development of choroidal neovascularization (CNV). Recently, photodynamic therapy or vitreous surgery is being successfully performed to restore vision but only in selected cases where photoreceptor degeneration is still fresh [2-7]. Recently, positive results of anti-vascular endothelial growth factor (VEGF) have accumulated [8,9], but the effect is limited in advanced stages. Furthermore, no effective treatment exists for eyes with geographic atrophy, drusen, and pigment alterations, so-called dry type. A growing volume of investigations have reported the keys to reveal the etiology, including the Age-related Eye Disease Study (AREDS), which provided a novel first step towards preventive medicine for the disease [10-14]. However, advanced damage cannot be restored. A polymorphism (Tyr402His) in the complement factor H (CFH) gene has recently been reported to increase the risk of AMD [15-17].

Recent reports have noted that electrical stimulation has neuroprotective potential by means of the enhancement of neurotrophic factors in several different neural tissues by subretinal implants [18,19]. Although the exact mechanism has yet to be elucidated, several investigators have shown the upregulation of neurotrophins in the central and peripheral nervous system in relation to electrical stimulation [20-22]. Thus, applying electrical stimulation to the retina may induce a protective effect on the diseased retina through the activation of the endogenous neuroprotective agents. It is, however, difficult to stimulate the retina electrically in a routine clinical environment. The subretinal implants were reported to upregulate neurotrophic factors, resulting in a protective effect on the remaining retinal circuitry [23,24]. The drawback to this novel treatment is that surgery is required. Morimoto et al. [20] reported a less invasive way based on the finding that novel transcorneal electrical stimulation rescues retinal ganglion cells by activating endogenous retinal IGF-1 system, which has long been known to evoke light sensations or cortical potentials that stem from inner retinal neurons [25-28].

These findings prompted us to examine the feasibility of utilizing transpalpebral electrical retinal stimulation therapy on patients with wet-type ARMD.

PATIENTS AND METHODS

Twenty-seven eyes with wet-type ARMD (Group W) and 7 eyes with dry-type ARMD (Group D) were studied. The patients consisted of 15 males and 1 female, aged 51 to 85 years with a mean of 73.3 ± 9.8 years (± SD) in Group W and 5 males, aged 63 to 85 years with a mean of 75.7 ± 9.2 years (± SD) in Group D. The procedures used conformed to the tenets of the Declaration of Helsinki, and written informed consent was obtained from each individual who participated in this study after explanation of the procedures. This prospective interventional case study was approved by the Institutional Review Board of Keio University Hospital. Eyes with a wet-type or dry-type ARMD lesion were recruited for this study. The lesion had to involve the geometric center of the foveal avascular zone.

Patients were excluded if they had any significant ocular disease other than subfoveal CNV or geographic atrophy, which affected visual acuity, a history of intraocular or laser surgery within 6 months, or if they had taken any medication used for AMD such as vitamins or lutein in the 6 months prior to the examination. Patients whose condition met the criteria of photodynamic therapy (PDT) or antiVEGF therapy of intravitreal pegaptanib injection, which was ongoing as a clinical trial, were also excluded. Consequently consecutive patients were enrolled. Eyes with pathologic myopia, which was defined as an eye that requires a distance correction of at least -6.0 diopters or eyes with an axial length of more than 26.5 mm, were also excluded.

A microcurrent of 800 μA was transpalpebrally applied to both eyes by using a microcurrent stimulator (Fig. 1, Skylark Device & Systems Co., Ltd., Taiwan). One session lasted for 20 minutes and was performed 4 times per day. The 20-minute protocol consisted of a monophasic pulse with a frequency of 290 Hz for 1 minute, 31 Hz for 2 minutes, 8.9 Hz for 10 minutes, and 0.28 Hz for 7 minutes. The transcorneal electrical stimulation was clinically applied using 300 to 2000 μA of 20 Hz stimulation for 30 minutes with an interval of one month to the patients with optic neuropathy [29]. The details of the protocol for electrical retinal stimulation have not yet been established, and the protocol in the transpalpebral electrical stimulation is to be determined.

Fig. (1).

Top: Appearance of the transcutaneous electrical retinal stimulation therapy. Top: The skin electrodes are applied to patches on both eyelids and the microcurrent runs through them. The patient remains seated during the 20-minute treatment. Bottom: The schema of the transcutaneous electrical retinal stimulation therapy. The [L] indicates eyelid. The [E] indicates cutaneous contact electrode. *: The dotted lines show the electrical current which is regulated in a symmetric bidirectional way.

Fig. (2).

Changes in visual function after the microcurrent therapy at 4 weeks. Top: The averaged Early Treatment Diabetic Retinopathy Study (ETDRS) visual acuity score significantly improved from 29.5±5.1 to 31.8±5.0 (mean±SE, P=0.0407) in wet-type age-related macular degeneration (ARMD) patients and in dry-type ARMD patients (from 39.8±4.7 to 42.9±4.9, P=0.0401). Bottom: The averaged mean deviation of the automated perimetry improved from -13.3±3.1 dB to -12.4±3.1 dB after treatment (mean±SE, P=0.0247) in wet-type ARMD patients while in dry-type ARMD patients, it changed from -9.3±3.2 dB to -9.3±2.8 dB (P>0.05). The ‘N.S.’ indicates ‘not significant’.

Fig. (3).

Subjective score in wet and dry-type age-related macular degeneration patients. Patients rated (poor, fair, good, and very good as 1, 2, 3, and 4, respectively) their subjective visual function change 4 weeks after treatment. The score showed no significant correlation with the other parameters such as visual acuity or the averaged mean deviation.

Best-corrected visual acuity testing, the Early Treatment Diabetic Retinopathy Study (ETDRS) score, slit-lamp examination, funduscopy, fluorescein angiography, and automated static visual field testing, were performed before and 4 weeks after the application of the daily microcurrent treatment. A masked examiner performed the visual acuity examinations. The results of Humphrey central 30-2 perimetry (Carl Zeiss Meditec, Dublin, CA) with more than 4 poor fixation (about 20% or more), more than 3 false positive data (33.3% or more), or more than 3 false negative data (33.3% or more) were excluded from the analysis. The mean deviation measured by Humphrey central 30-2 perimetry (Carl Zeiss Meditec, Dublin, CA), which assesses the sensitivity distribution in the central retinal area, was used for statistical evaluation.

The patients were asked 4 weeks after the treatment to rate the subjective therapeutic effect as poor, fair, good, and very good. For analysis the result was converted to scores of 1, 2, 3, and 4 as poor, fair, good, and very good, respectively.

For the statistical procedure, visual acuity of 'counting fingers' and 'hand motion' were assigned to 20/20000 and 20/200000, respectively, according to the previous report [30]. The paired t-test was performed to determine the changes of visual acuity and the mean deviation of the automated static perimetry.

RESULTS

All the patients reported phosphene when the microcurrent was provided. This can be interpreted that the retina was electrically stimulated. Best-corrected visual acuity before and 4 weeks after treatment is shown in the Table 1.

Table 1.

Snellen Visual Acuity

  Wet-Type Dry-Type
ARMD1 (n2=27) ARMD (n=7)
Pre-treatment C.F.3 – 20/25 20/1000– 20/50
20/400 20/160
Post-treatment 20/100 – 20/32 20/100 – 20/40
20/400 20/200

Data are shown as range (median).

1ARMD = age-related macular degeneration.

2n=number of eyes, 3C.F = counting fingers.

Table 2.

ETDRS Score and Mean Deviation

Case Gender Age Laterality Type ETDRS Score Mean
Deviation
Pre Post Pre Post
Tx Tx Tx Tx
1 M 83 L W 36 46 -6.3 -7.36
2 M 71 R W 79 77 -6.71 -1.44
L W 18 21 -11.22 -7.18
3 M 75 R W 33 37 -17.93 -14.86
L W 5 8 -21.48 -18.09
4 M 81 R W 1 2 -18.69 -21.54
L W 50 52 -1.98 -3.22
5 M 71 L W 19 22 -10.54 -9.63
6 M 62 R W 62 64 -4.34 -2.77
L W 57 65 -8.5 -8.32
7 M 51 R W 43 54 -4.61 -5.29
8 M 68 R W 72 67 -4.37 -2.64
L W 26 21 -3.42 -6.23
9 M 85 R W 0 4 -28.94 -27.76
10 M 57 R W 70 65 -4.89 -4.32
L W 41 39 -4 -4.63
11 M 72 R W 3 8 -29.56 -27.27
L W 0 4 -30.03 -28.33
12 M 84 L W 19 18 -11.13 -8.07
13 F 79 R W 15 18 -29.34 -28.09
L W 0 1 -28.96 -29.02
14 M 77 R W 17 23 -10.29 -9.22
L W 1 20 -12.75 -14.04
15 M 79 R W 3 2 -25.22 -26.03
L W 9 6 -15.18 -13.45
16 M 78 R W 45 48 -4.45 -3.61
L W 72 66 -3.5 -1.55
1 M 71 R D 26 31 -2.84 -3.57
2 M 84 R D 68 71 -3.71 -9.46
3 M 85 L D 39 42 -13.02 -9.63
4 M 76 R D 7 5 -25.57 -23.46
L D 35 35 -18.96 -14.26
5 M 63 R D 36 42 -1.47 -2.43
L D 68 74 0.58 -2.36

M: male; F: female; R: right: L: left; W: wet type; D: dry type; mean deviation is shown as value (dB); ETDRS: Early Treatment Diabetic Retinopathy Study.

Although the improvement of visual acuity did not reach statistical significance in the entire group, the average of the ETDRS scores significantly improved from 29.5±5.1 to 31.8±5.0 (mean±SE, P=0.0407, paired t-test, Fig. (2 top), Table 2) in Group-W and from 39.8±4.7 to 42.9±4.9 in Group-D (P=0.0401, paired t-test, Fig. (2 top), Table 2). The averaged mean deviation of the automated perimetry in Group-W was -13.3±3.1 dB before treatment and -12.4±3.1 dB after treatment (mean±SE, P=0.0247, paired t-test, Fig. (2 bottom), Table 2). However, in Group-D, no significant improvement was shown; from -9.3±3.2 dB to -9.3±2.8 dB (P>0.05, paired t-test, Fig. (2 bottom), Table 2).

The subjective score in each group is shown in Fig. (3). Generally patients were satisfied and preferred to continue the treatment. However, it showed no significant correlation with the other parameters, such as visual acuity and the averaged mean deviation. No obvious change was observed either by slit-lamp or funduscopy. No ocular and systemic complications were observed except one patient who developed contact dermatitis on both superior lids. We decided to stop treatment, considering the adverse side effect to be serious, despite the 62-year-old man’s strong preference to continue the treatment and instead initiated treatment using ofloxacin ointment.

CONCLUSIONS

A number of trials have been performed to develop an effective way to control the progression and complications of ARMD, but it remains limited [2-7]. This is attributed to the lack of understanding of the pathogenesis and final irreversible damage of the neural network including photoreceptor cells. Recently, subretinal implants were reported to have a protective effect on the remaining retinal neurons, possibly by means of upregulating neurotrophic factors [19,23,24]. Consequently, the electrical stimulation of the retinal circuit might have a potential neuroprotective effect on the degenerating retina. Survival of photoreceptors following transcorneal electrical stimulation was reported in Royal College of Surgeons’ rats [31]. Therefore, we performed a pilot study to investigate a therapeutic effect of electrical retinal stimulation on the degenerating retina. A novel treatment, transcorneal electrical stimulation, invented by Morimoto et al. [20] showed dramatic advancement compared with subretinal implantation of an electrical device. However, that procedure is invasive, especially on the cornea, and requires clinical treatment. The current study shows a less invasive way that can be performed by the patient himself even at home.

In the 1960s, a number of investigators reported clinical application of electrical retinal stimulation for evaluating retinal function, but not for treatment [25-28]. In such investigations, normally the electrical stimulation was provided using a corneal contact lens and no severe adverse effects were reported. As expected, in the current study, serious adverse effects, such as severe vision loss or corneal erosion, were not seen. One case among a total of 23 cases (4.3%) developed contact dermatitis, which should be considered an inherent complication of the therapy. In this case, it was not severe, treatment was stopped and the application of ofloxacin ointment led to immediate disappearance of the dermatitis. Such complications might be avoided by using a different material for attaching the skin electrodes. Since this is an almost completely new treatment, it would be necessary for clinicians to be reminded that there might be some other unknown potential hazard.

Our results demonstrated that the microcurrent retinal stimulation has the potential of improving retinal function of the wet-type ARMD, although these are preliminary results and the study’s weaknesses limit the generalization of the findings: small number of patients studied, relatively short follow-up times, and absence of a control group. Therefore, the findings from this study cannot be interpreted as justifying the definite efficacy of the microcurrent therapy for ARMD. The information and data obtained from this study are, however, useful in that they bring to light the future possibility of novel alternative treatment for a refractory age-related eye disease. In the present study, the wet-ARMD seemed to benefit, whereas the dry-AMD did not in terms of visual field parameter. It is speculated that the photoreceptor cell and/or RPE cell, which benefits this therapy, should be freshly or mildly damaged, and that relative acute damage in wet-type ARMD could be recovered. Further investigation of larger numbers and a longer observation period designed as a randomized control trial and also basic research will be necessary to determine the feasibility of the therapy, and to understand the therapeutic role of the microcurrent on the progressively degenerating photoreceptors.

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