ABSTRACT
The management of optic neuropathy is fundamental to neuro-ophthalmic practice. Following the invention of the ophthalmoscope, clinicians, for a century or more, relied upon fundus examination in the evaluation of optic neuropathy. However, the advent of optical coherence tomography, based on the principle of backscattering of light and interferometry, has revolutionized the analysis of optic nerve and retinal disorders. Optical coherence tomography has proven of particular value in the measurement, at the micron level, of the peripapillary retinal nerve fibre layer and the ganglion cell layer. These measurements have proven critical in the differential diagnosis and monitoring of optic neuropathy. Specifically, thinning of the peripapillary nerve fibre layer provides evidence of axonal loss affecting any sector of the optic nerve. Thinning of the macular ganglion cell layer, on the other hand, shows a more precise correlation with visual deficits due to retrograde degeneration following optic nerve damage, although limited to central retina. In daily practise, optical coherence tomography is of great value in assessing the diagnosis, prognosis and response to treatment in optic neuropathy. Particular advances have been made, for example, in the assessment of optic neuritis, papilloedema and chiasmal compression which have translated to everyday practice. As with any other imaging technology the clinician must have a clear understanding of acquisition artefacts. A further issue is the relatively limited normative database in sub-populations such as the young and individuals with a refractive error > + 5 or < -5 dioptres.
ABSTRACT
PURPOSE: To describe the frequency and characteristics of intraretinal and subretinal fluid in nonarteritic anterior ischemic optic neuropathy (NAAION) and to assess the influence on the visual deficit and optic nerve fiber/ganglion cell loss. DESIGN: A retrospective, single-center study. PARTICIPANTS: Thirty-two patients with NAAION referred to our Neuro-ophthalmology Department between 2014 and 2021. METHODS: The study was carried out at the University Hospital of Liège, Belgium. For participants in whom subretinal fluid was identified on standard OCT (Carl Zeiss Meditec) an additional macular OCT (Spectralis Heidelberg) had been performed. The pattern and the maximal height of the retinal fluid were determined manually, and thicknesses of retinal layers were obtained using the OCT protocol analysis. RESULTS: The mean age of the cohort was 60 years (standard deviation, ±12.5; range, 22-88 years), and 65.6% were male. In the 21 eyes (46.7%) in which retinal fluid was observed, macular OCT findings were categorized according to fluid localization: 19 cases had parafoveal fluid (of whom 9 also had subfoveal fluid). One patient had subfoveal fluid alone, and 1 patient had peripapillary subretinal fluid alone. Specific patterns of optic disc (OD) swelling were associated with the occurrence and distribution of retinal edema. Visual acuity, visual field loss, and foveal thresholds were stable over the period of observation (P = 0.74, P = 0.42, and P = 0.36, respectively). No difference was found in visual function at 6 months between patients with retinal fluid treated (n = 10) or not treated (n = 11) with corticosteroids (visual acuity, P = 0.13; foveal threshold, P = 0.59; mean deviation, P = 0.66). CONCLUSIONS: Subretinal fluid is found in a high proportion of cases of NAAION. Visual function remained largely stable from presentation in this cohort. Corticosteroid intake at presentation did not influence visual recovery or timing of the resorption of tissue edema. Our findings do not support treatment of NAAION with corticosteroids with or without evidence of subretinal fluid acutely. With regard to pathogenesis, we propose that the volume of transudate generated at the OD is the critical factor rather than dysfunction of retinal mechanisms subserving reabsorption. FINANCIAL DISCLOSURE(S): Proprietary or commercial disclosure may be found in the Footnotes and Disclosures at the end of this article.
ABSTRACT
Purpose: Microcystic macular edema (MME), also known as retrograde maculopathy (RM), is associated with severe optic atrophy because of a range of causes. However, similar changes have also been described in primary retinal pathology and the pathogenesis of MME is debated. Design: A retrospective observational case series. Participants: Patients with nonarteritic ischemic optic neuropathy. Methods: A retrospective observational case series was performed at the University Hospital of Liège, Belgium. The medical records of patients who were referred to our Neuro-ophthalmology department with a diagnosis of nonarteritic anterior ischemic optic neuropathy (NA-AION), between 2014 and 2021, were reviewed. Main Outcome Measures: Ganglion cell complex thickness, acute and chronic inner nuclear change. Results: In a cohort of 34 patients (mean age: 60 ± 12.5 years; 65.6% men) with NA-AION, we identified a transient microcystic change in the inner nuclear layer (INL) associated with optic disc swelling in 19 eyes at presentation. This early change was associated with a transudate of intraretinal and subretinal fluid originating from the optic disc. Among patients who had shown this transient change 3 subsequently developed MME, which remained fixed during the period of observation (range, 12-34 months). No MME was observed in patients without an early INL transient change. Microcystic macular edema was observed in patients with severe ganglion cell complex thinning at 6 months: mean (± SD) loss in superior hemimacula (-28.2 ± 5.2 µm [-33.3%, range, -22.3 to -30.3 µm]) and in inferior hemimacula (-30.7 ± 5.6 µm [-31.0%, range, -24.3 to 34.8 µm]). Conclusions: Our study has revealed 2 causes of INL cystic change in the same patients experiencing NA-AION, 1 reversible and the other likely permanent. This finding highlights the distinction between genuine edema related to transudation of fluid (in this case secondary to ischemic optic disc swelling) and the phenomenon observed in RM that is related to the degree of retinal nerve fiber layer/ganglion cell complex thinning. Cystic change in the INL is associated with severe optic atrophy (MME). However, similar changes have been described in retinal pathology and the pathogenesis of MME is debated.
