Idiopathic Juxtafoveolar Retinal Telangiectasis: A Current Review

The highly impermeable tight junctions between endothelial cells forming the capillaries and venules in the central nervous system (CNS) of higher vertebrates are thought to be responsible for the blood-brain barrier that impedes the passive diffusion of solutes from the blood into the extracellular space of the CNS. The ability of CNS endothelial cells to form a blood-brain barrier is not intrinsic to these cells but instead is induced by the CNS environment: Stewart and Wiley demonstrated that when avascular tissue from 3-day-old quail brain is transplanted into the coelomic cavity of chick embryos, the chick endothelial cells that vascularize the quail brain grafts form a competent blood-brain barrier; on the other hand, when avascular embryonic quail coelomic grafts are transplanted into embryonic chick brain, the chick endothelial cells that invade the mesenchymal tissue grafts form leaky capillaries and venules. It is, however, not known which cells in the CNS are responsible for inducing endothelial cells to form the tight junctions characteristic of the blood-brain barrier. Astrocytes are the most likely candidates since their processes form endfeet that collectively surround CNS microvessels. In this report we provide direct evidence that astrocytes are capable of inducing blood-brain barrier properties in non-neural endothelial cells in vivo.

Idiopathic juxtafoveolar retinal telangiectasis may cause visual loss. The treatment of this disease is controversial. The authors reviewed the records of 140 patients with idiopathic juxtafoveolar telangiectasis. A classification scheme based on biomicroscopic and fluorescein angiographic findings is presented. In addition, the effect of photocoagulation on the natural history of the disorder is evaluated. Patients are categorized into three groups. Group 1 comprises 39 male patients with nonfamilial, easily visible telangiectasis and intraretinal exudation. The telangiectasis is unilateral in 94% of patients. The telangiectasia in this group is probably of developmental origin (Coats syndrome). Group 2 comprises 94 patients with occult juxtafoveolar telangiectasis, minimal exudation, superficial retinal crystalline deposits, and right-angle venules. Late in the course of the disease, foveolar atrophy, intraretinal pigment plaques, and subretinal neovascularization develop. The telangiectasis is acquired during middle age and is bilateral in 98% of patients. Group 3 comprises seven patients with bilateral easily visible telangiectasis, minimal exudation, and capillary occlusion. All of these patients had systemic disease, which was probably related to their eye disease. Slow visual loss beginning in adulthood characterizes most of these patients. The telangiectasis appears to be caused primarily by retinal capillary leakage in group 1, capillary diffusion abnormalities in group 2, and capillary occlusion in group 3. Photocoagulation is probably beneficial for patients in group 1 and not for patients in group 2, at least before their development of subretinal neovascularization.

(1) The blood-brain barrier (BBB) is formed by brain capillary endothelial cells (ECs). There are various cell types, in particular astrocytes, but also pericytes and neurons, located in close vicinity to the capillary ECs which may influence formation and function of the BBB. Based on this consideration, this paper discusses various aspects of the influence of the surrounding cells on brain capillary ECs with special focus on the role of astrocytes. (2) Based on the morphology of the BBB, important aspects of brain EC functions are summarized, such as transport functions and maintenance of low paracellular permeability. Moreover, various facets are discussed with respect to the influence of astrocytes, pericytes, microglia, and neurons on the BBB. Data on the role of glial cells in the ontogenesis of the BBB are presented subsequently. The knowledge on this subject is far from being complete, however, these data imply that the neural/neuronal environment rather than glial cells may be of importance in the maturation of the barrier. (3) The role of glial cells in the induction and maintenance of the BBB is discussed under physiological as well as pathological conditions. Although the literature presents manifold evidence for a great variety of effects induced by astroglia, there are also many controversies, which may result from different cellular models and experimental conditions used in the respective studies. Numerous factors secreted by astrocytes have been shown to induce a BBB phenotype. On the molecular level, increased expression of barrier-relevant proteins (e.g., tight junction proteins) is documented in the presence of astrocyte-derived factors, and many studies demonstrate the improvement of physiological parameters, such as increased transendothelial resistance and decreased paracellular permeability, in different in vitro models of the BBB. Moreover, one has to take into account that the interaction of brain ECs and astrocytes is bi-directional, and that the other cell types surrounding the brain microvasculature also contribute to BBB function or dysfunction, respectively. (4) In conclusion, it is expected that the present and future research focused on molecular mechanisms and signaling pathways will produce new and exciting insights into the complex network of BBB regulation: the cornerstone is laid.