Antiangiogenic therapy for ischemic retinopathies

Age-Related Macular Degeneration: Pathogenesis, Genetic Background, and the Role of Nutritional Supplements

Age-related macular degeneration (ARMD) is the leading cause of severe vision loss and blindness worldwide, mainly affecting people over 65 years old. Dry and wet ARDM are the main types of the disease, which seem to have a multifactorial background. The aim of this review is to summarize the mechanisms of ARMD pathogenesis and exhibit the role of diet and nutritional supplements in the onset and progression of the disease. Environmental factors, such as smoking, alcohol, and, diet appear to interact with mutations in nuclear and mitochondrial DNA, contributing to the pathogenesis of ARMD. Inflammatory mediators and oxidative stress, induced by the daily exposure of retina to high pressure of oxygen and light radiation, have been also associated with ARMD lesions. Other than medical and surgical therapies, nutritional supplements hold a significant role in the prevention and treatment of ARMD, eliminating the progression of macular degeneration.

MicroRNA-dependent cross-talk between VEGF and HIF1α in the diabetic retina

Both HIF1α (hypoxia-inducible factor alpha) and VEGF (vascular endothelial growth factor) are implicated in the pathogenesis of diabetic retinopathy (DR). Competitive endogenous RNAs (ceRNAs) are messenger RNA (mRNA) molecules that affect each other expression through competition for their shared microRNAs (miRNA). However, little is known about the role of ceRNAs in DR. We assess whether the expression of HIF1α and VEGF in DR is interdependent through sequestration of common miRNAs. We used bioinformatics to identify potential miRNAs that affect both genes and validated the interdependence of the genes by silencing or overexpression of the genes and assessed the luciferase-HIF1α 3'UTR activity. We found that HIF1α and VEGF are targeted by 12 common miRNAs. Silencing either HIF1α or VEGF increased the availabilities of the shared miRNAs, therefore suppressed the luciferase-HIF1α 3'UTR activity, whereas over-expressing HIF1α or VEGF increased the luciferase activity. HIF1α was co-expressed with VEGF in-vivo and in-vitro in DR models. Silencing HIF1α transcripts resulted in a significant reduction in VEGF protein levels and vice versa. This interdependence was miRNA- and 3'UTR-dependent, as silencing Dicer abolished the interdependence. Over-expression of a common miRNA (miR-106a) significantly reduced the expression of HIF1α and VEGF and prevented high glucose-induced increased permeability. There is a cross-talk between HIF1α and VEGF through interactions with their common miRNAs. miRNA based therapy can affect the expression of both HIF1α and VEGF and may represent a therapeutic potential for the treatment of DR.

Identification of novel drug targets for the treatment of diabetic retinopathy

Vision loss in diabetic retinopathy (DR) is attributable to retinal vascular disorders that result in macular edema and neoangiogenesis. In addition to laser photocoagulation therapy, intraocular injections of antivascular endothelial growth factor drugs have contributed to the treatment of these disease conditions. Nonetheless, the clinical feasibility of intraocular drug administration has raised an increasing demand to develop alternative drugs that can fundamentally ameliorate the retinal vascular dysfunctions in DR. For this purpose, experimental animal models that reproduce human DR would be of clinical benefit. Despite the unavailability of DR models in rats or mice, pharmacological and genetic manipulations without hyperglycemia have successfully recapitulated retinal edema and neoangiogenesis in postnatal mouse retinas, thereby enabling the understanding of the pathophysiology underlying DR. This article highlights the utility of experimental mouse models of retinal vascular abnormalities and discusses cellular and molecular mechanisms responsible for the onset and progression of DR. These approaches will lead to the identification of novel drug targets for the restoration of vascular integrity and regeneration of functional capillaries in DR.

Compartment model predicts VEGF secretion and investigates the effects of VEGF trap in tumor-bearing mice

Angiogenesis, the formation of new blood vessels from existing vasculature, is important in tumor growth and metastasis. A key regulator of angiogenesis is vascular endothelial growth factor (VEGF), which has been targeted in numerous anti-angiogenic therapies aimed at inhibiting tumor angiogenesis. Systems biology approaches, including computational modeling, are useful for understanding this complex biological process and can aid in the development of novel and effective therapeutics that target the VEGF family of proteins and receptors. We have developed a computational model of VEGF transport and kinetics in the tumor-bearing mouse, which includes three-compartments: normal tissue, blood, and tumor. The model simulates human tumor xenografts and includes human (VEGF121 and VEGF165) and mouse (VEGF120 and VEGF164) isoforms. The model incorporates molecular interactions between these VEGF isoforms and receptors (VEGFR1 and VEGFR2), as well as co-receptors (NRP1 and NRP2). We also include important soluble factors: soluble VEGFR1 (sFlt-1) and α-2-macroglobulin. The model accounts for transport via macromolecular transendothelial permeability, lymphatic flow, and plasma clearance. We have fit the model to available in vivo experimental data on the plasma concentration of free VEGF Trap and VEGF Trap bound to mouse and human VEGF in order to estimate the rates at which parenchymal cells (myocytes and tumor cells) and endothelial cells secrete VEGF. Interestingly, the predicted tumor VEGF secretion rates are significantly lower (0.007-0.023 molecules/cell/s, depending on the tumor microenvironment) than most reported in vitro measurements (0.03-2.65 molecules/cell/s). The optimized model is used to investigate the interstitial and plasma VEGF concentrations and the effect of the VEGF-neutralizing agent, VEGF Trap (aflibercept). This work complements experimental studies performed in mice and provides a framework with which to examine the effects of anti-VEGF agents, aiding in the optimization of such anti-angiogenic therapeutics as well as analysis of clinical data. The model predictions also have implications for biomarker discovery with anti-angiogenic therapies.

Vascular changes in eyes treated with dexamethasone intravitreal implant for macular edema after retinal vein occlusion

OBJECTIVE

To evaluate the angiographic findings in eyes from 2 clinical trials of the dexamethasone intravitreal implant (DEX implant) 0.7 mg in the treatment of macular edema (ME) after branch retinal vein occlusion (BRVO) or central retinal vein occlusion (CRVO).

DESIGN

Post hoc analysis of pooled data from 2 identical phase 3 clinical trials.

PARTICIPANTS

Patients with vision loss as a result of ME (≥ 6 weeks' duration) after BRVO or CRVO for whom angiographic data were available (n = 329 eyes).

METHODS

Fluorescein angiography (FA) results assessed by masked, certified graders using standardized grading protocols.

MAIN OUTCOME MEASURES

The primary outcome measure in the parent studies was change from baseline in best-corrected visual acuity. Prospectively defined secondary outcomes included FA measurements (to assess macular capillary leakage, neovascularization, and nonperfusion) and optical coherence tomography results (to assess central retinal thickness [CRT]).

RESULTS

At baseline, 42% of eyes in the DEX implant group and 38% of eyes in the sham group had unreadable assessments because of hemorrhage. At day 180, significantly fewer DEX implant-treated eyes (2%) than sham-treated eyes (9%) had unreadable assessments because of hemorrhage (P = 0.029). Among eyes with gradable assessments, the incidence of nonperfusion remained fairly steady from baseline to day 180. The proportion of eyes with active neovascularization increased from baseline to day 180 in the sham group, but stayed relatively constant in the DEX implant group (P = 0.026 for DEX vs. sham). The mean area of overall nonperfusion and the mean area of macular capillary nonperfusion increased from baseline to day 180 in both treatment groups (no statistically significant between-group difference). There was a statistically significant positive correlation between changes in macular leakage and changes in CRT in both the DEX implant group (r = 0.22; 95% confidence interval, 0.03-0.40; P = 0.023) and the sham group (r = 0.29; 95% confidence interval, 0.10-0.46; P = 0.003).

CONCLUSIONS

This study demonstrated that the clinical improvements observed with the DEX implant were accompanied by significant improvements in vascular parameters and suggests that treatment with the DEX implant may be associated with some clinically significant improvements in angiographic findings, specifically active neovascularization.

Molecular basis of the inner blood-retinal barrier and its breakdown in diabetic macular edema and other pathological conditions

Breakdown of the inner endothelial blood-retinal barrier (BRB), as occurs in diabetic retinopathy, age-related macular degeneration, retinal vein occlusions, uveitis and other chronic retinal diseases, results in vasogenic edema and neural tissue damage, causing loss of vision. The central mechanism of altered BRB function is a change in the permeability characteristics of retinal endothelial cells caused by elevated levels of growth factors, cytokines, advanced glycation end products, inflammation, hyperglycemia and loss of pericytes. Subsequently, paracellular but also transcellular transport across the retinal vascular wall increases via opening of endothelial intercellular junctions and qualitative and quantitative changes in endothelial caveolar transcellular transport, respectively. Functional changes in pericytes and astrocytes, as well as structural changes in the composition of the endothelial glycocalyx and the basal lamina around BRB endothelium further facilitate BRB leakage. As Starling's rules apply, active transcellular transport of plasma proteins by the BRB endothelial cells causing increased interstitial osmotic pressure is probably the main factor in the formation of macular edema. The understanding of the complex cellular and molecular processes involved in BRB leakage has grown rapidly in recent years. Although appropriate animal models for human conditions like diabetic macular edema are lacking, these insights have provided tools for rational design of drugs aimed at restoring the BRB as well as for design of effective transport of drugs across the BRB, to treat the chronic retinal diseases such as diabetic macular edema that affect the quality-of-life of millions of patients.

Tissue factor with age-related macular degeneration

Wet age-related macular degeneration which incidence increases year by year is a blinding eye disease, but current clinical methods of treatment on this disease are limited and the outcome is not ideal. Recent studies have found abnormally high expression of tissue factors which are targets for the treatment of wet age-related macular degeneration to achieve a certain effect in the choroidal neovascularization. Related literatures are reviewed as following.