Abstract: Hereditary, metabolic and toxic optic neuropathies cause bilateral, central vision loss and therefore can result in severe impairment in visual function. Accurate, early diagnosis is critical, as nutritional and toxic optic neuropathies may be reversible if identified early, and diagnosis of hereditary optic neuropathies can prevent unnecessary invasive workup, provide prognostic information, and allow for effective genetic counseling. Optical coherence tomography (OCT) is a valuable tool that aids in the diagnosis and prognostication of optic neuropathies as it allows for quantification of changes in the retinal ganglion cells (RGCs) and retinal nerve fiber layer (RNFL) over time. We review the characteristic clinical presentations of hereditary, metabolic and toxic optic neuropathies, with an emphasis on OCT findings.

Abstract: The purpose of this article is to review current literature and data regarding treatment options for age-related macular degeneration (AMD) related to mitochondrial therapy. This article considers the presence of flavoprotein fluorescence as a potential biomarker to test the effectiveness of the treatments. We focus primarily on two major mitochondrial targets, nuclear factor erythroid 2-related factor (NFE2L2) and PGC-1α, that function in controlling the production and effects of reactive oxidative species (ROS) directly in the mitochondria. PU-91 is an FDA approved drug that directly targets and upregulates PGC-1α in AMD cybrid cell lines. Although neither NFE2L2 nor PGC1-α have yet been tested in clinical trials, their effects have been studied in rodent models and offer promising results. MTP-131, or elamipretide^?, and metformin are two drugs in phase II clinical trials that focus on the treatment of advanced, non-exudative AMD. MTP-131 functions by associating with cardiolipin (CL) whereas metformin targets adenosine-monophosphate protein kinase (AMPK) in the mitochondria. The current results of their clinical trials are elucidated in this article. The molecular targets and drugs reviewed in this article show promising results in the treatment of AMD. These targets can be further pursued to improve and refine treatment practices of this diagnosis.

Background: The ex vivo model represented by mouse retinal explants in culture is a useful experimental model to investigate the molecular mechanism involved in neurovascular diseases such as diabetic retinopathy (DR). It ensures an experimental overview with more complete respect to isolate cells and reduce problems in terms of accessibility and management with respect to in vivo model. In particular, it allows the evaluation of the relationship between retinal cells in response to the typical stressors involved in DR pathogenesis.

Methods: Ex vivo retinal fragments derived from 3- to 5-week-old C57BL/6J mice. In particular, after dissection, the retina is cut into 4 separate fragments and transferred onto inserts placed with ganglion cells up. Once in culture, the explants could be treated in stress conditions typical of DR. In particular, this study protocol describes the procedure for the preparation and the culture of retinal explants with specific metabolic stressors such as high glucose (HG), advanced glycation end product (AGE), and oxidative stress (OS). In the end, this paper provides the protocols to perform molecular analyses in order to evaluate the response of retinal explants to stress and/or neuroprotective treatments.

Discussion: The cultured retinal explants represent an ex vivo experimental model to investigate the molecular mechanisms involved in neurovascular diseases such as DR. Moreover, they could be useful to test the effect of neuroprotective compounds in response to metabolic stressors in a fewer time respect to an in vivo model. In conclusion, retinal explants in culture represent a valuable experimental model to conduct further studies to better understand the pathophysiology of DR.