Tsuyoshi Otsuji

Pathologic features of vascular endothelial growth factor-induced retinopathy in the nonhuman primate

PURPOSEnVascular endothelial growth factor (VEGF) is a potent ischemia-upregulated angiogenic protein that has been implicated in diabetic retinopathy. Intravitreal VEGF injections have not previously been shown to produce preretinal neovascularization. The purpose of this study was to further characterize the angiopathic changes that occur after intravitreal injections in a nonhuman primate and determine if preretinal neovascularization develops.nnnDESIGNnExperimental animal study.nnnMETHODSnVascular endothelial growth factor 165 was injected into the eyes of normal cynomolgus monkeys at regular intervals. As a control, normal eyes were injected with phosphate buffered saline. Color photography and fluorescein angiography were performed at regular intervals. The retinas were incubated for adenosine diphosphatase (ADPase) activity to visualize retinal vessels. The retinas were flat-embedded and areas of potential preretinal neovascularization were identified en bloc and serially sectioned.nnnRESULTSnAreas of capillary nonperfusion and vessel dilation and tortuousity were seen by angiography. In serial sections, the nonperfused areas were found to be associated with endothelial cell hyperplasia in vessel lumens. Preretinal neovascularization originating only from superficial veins and venules was observed throughout peripheral retina, but was not seen in the posterior pole. Lacunae-like veins were subdivided by the process of intussusception and endothelial cell bridging. Arterioles demonstrated endothelial cell hyperplasia and microaneurysms.nnnCONCLUSIONnIntraocular injections of VEGF were sufficient to produce preretinal neovascularization in the nonhuman primate. Most vasculopathic structures were associated with endothelial cell hyperplasia. These results demonstrate that VEGF alone can produce many features of both nonproliferative and proliferative diabetic retinopathy including the previously undescribed development of preretinal neovascularization. This well-characterized VEGF-induced primate model of retinal neovascularization may be useful as a means of testing new treatments for retinal neovascularization.

Mechanisms for sickle red blood cell retention in choroid.

Purpose. Although sickle (SS) red cell-mediated vaso-occlusion in retina and resultant retinopathy is well documented, the effects of SS red cells on choroidal vasculature are poorly understood. The intent of this study was to determine, using a rat model, the conditions under which retention of sickle erythrocytes in choroid occur and if that retention can be inhibited. Methods. Sickle red cells were density separated into high density (SS4) or normal density, reticulocyte-enriched fractions (SS2). Red cells were labeled with FITC and administered IV to anesthetized Sprague Dawley rats. Rats were made either hypoxic or were given TNF-a intraperitoneally 5 hours before intravenous administration of red cells. Five minutes after administration of red cells, rats were exsanguinated, the retinas removed, and choroids prepared as flat-mounts. The number of red cells retained in five high power fields of choroid was then determined. In other experiments, SS red cells were preincubated with the cyclic peptide TBC772 [inhibits binding of a4ß1 (VLA-4) and a4ß7 to their ligands], a control peptide TBC1194, or a VLA-4 neutralizing antibody before administration to the rat or antibodies against VLA-4 ligands were delivered IV before administration of SS red cells. Results. Hypoxic conditions before administration of SS red cells significantly stimulated retention of SS4 cells (P = 0.0003), but did not significantly increase retention of SS2 cells. Administration of TNF-a significantly increased retention of all types of SS red cells (P < 0.001). Preincubation of cells with anti-VLA-4 or TBC 772 inhibited retention of SS red cells in choriocapillaris of TNF-a-treated rats (P < 0.0001). Complete inhibition of cytokine-stimulated retention was also accomplished by IV administration of mono-clonal antibodies against fibronectin or its CS-1 domain, a ligand for VLA-4. Conclusions. The mechanisms for retention of SS red cells in retina and choroid appear identical: hypoxia-mediated retention of dense red cells and adherence of red cells in reticulocyte-rich fractions after cytokine stimulation. TNF-a-stimulated retention of SS red cells in choroid appears to be mediated by VLA-4, presumably on the surface of some reticulocytes. This increased retention was inhibited by a VLA-4 antagonist (TBC772), a VLA-4 neutralizing antibody or by blocking one of VLA-4s ligands, the CS-1 portion of fibronectin.

Preliminary ocular histopathological observations on heterozygous NEMO-deficient mice

The majority of patients with incontinentia pigmenti (IP) have a mutation in the nuclear factor-kappa-beta essential modulator (NEMO) gene, and mice with a targeted deletion of NEMO exhibit skin pathology remarkably similar to the human disease. This study characterizes the retinal vascular abnormalities of NEMO-deficient mice, and compares this phenotype to known features of human IP. Nineteen heterozygous NEMO-deficient female mice, ages ranging from post-natal day 8 (P-8) through 6.5 months of life, were studied. Eyes were sectioned and stained either whole or as retinal flat mounts after incubation for enzyme histochemical demonstration of ADPase, which labels the vasculature. With maturation, retinal arteriolar abnormalities became evident at 3 months of age. Global assessment of the retinal vasculature with ADPase staining showed increased vascular tortuosity. Microscopic examination of sections of ADPase-incubated retinas revealed arteriolar luminal narrowing due to endothelial cell hypertrophy and increased basement membrane deposition. Venous morphology was normal. This study characterized the histological retinal phenotype of heterozygous NEMO-deficient female mice. Most striking were retinal arteriolar abnormalities, including luminal narrowing, endothelial cell hypertrophy, and basement membrane thickening. Retinal flat mounts revealed arteriolar tortuosity without evidence of vaso-occlusion or neo-vascularization.