Vitreoretinal interface is consisted of posterior vitreous cortex, retina internal limiting membrane, and extracellular matrix between them. Basement membrane-like complex is formed in the interface. The interface in children is of much difference with that in adult. The adhesion of it is much tight in children. The posterior edge of vitreous base is closed to ora serrata. The retina internal limiting membrane is thin. But with age, the posterior margin of vitreous base extends posteriorly, internal limiting membrane thickens and its elasticity decreases, the adhesion in vitreoretinal interface weakens, and posterior vitreous detachment develops. To recognize fully the interface in children is of much importance for understanding the pathophysiology and treatment strategy of pediatric vitreoretinal diseases.
Objective To evaluate the correlation between antiphospholipid (APLA) antibodies and retinal vein occlusion (RVO). Methods A computerized search was conducted in the Pubmed, Chinese Biological Medicine Database, China National Knowledge Infrastructure, VIP database, Wanfang Database combined with manually searching of literature reference proceedings. The search time was ranged from establishment of each database to August 1st, 2012. After the data extraction, quality of RCT was assessed. The meta analysis was performed by Stata 11.0. Results In total, 12 case-control studies (1324 subjects) that fulfilled the eligibility criteria were included in the meta-analysis involving 505 patients in RVO group and 819 subjects in control group. The odds ratio (OR) and 95% confidence interval (CI) of APLA, anticardiolipin antibodies (ACA), lupus coagulation inhibitor and RVO were 5.01 and 3.33 - 7.53,4.38 and 2.38 - 8.05, 1.72 and 0.73 - .88, 6.02 and 2.06 - 17.63, respectively. The OR and 95% CI of APLA, ACA, lupus coagulation inhibitor and branch RVO were 4.22 and 1.67 - 10.63, 3.69 and 1.32 - 10.32, 2.07 and 0.79 - 5.41, respectively. Conclusions APLA may increase the rick of RVO, especially ACA has a prediction function to RVO. It is necessary to screening for APLA in RVO patients.
ObjectiveTo investigate the gene expression spectrum of retina and optic nerve after partial injury of optic nerve.MethodsSixty SD rats were randomly divided into 4 groups. The optic nerves of the right eyes were clipped for 6 seconds with a pair of crossaction forceps. The retinae and optic nerves in the operation eye and contralateral sham operation eye were removed 3, 7, 14, and 21 days after the injury to detect gene expression patterns with high-density DNA microarrays.ResultsChanges of a mass of gene expressions were found after the optic nerve injury, and the positive rate of gene expression was 2.35%, 6.48%, 3.82% and 4.09% after 3, 7, 14, 21 days, respectively, and the total positive rate was 11.77%. The functions of positive expression of the gene involved cell survival, cytoskeleton, extracellular matrix and cell adhesion, free radicals and oxidative damage, energy and metabolism, inflammation, neurotransmission and ion transport, signal transduction, structural protein, transcription and translation. Up-or down-regulation of repaired genes was the main part of the changes of gene expression, while the alteredexpression destroy genes was the minor part in the whole gene expression spectrum, in which the up- and down-regulation of expression of repaired genes accounted for 13.98% and 24.73% respectively 7 days after the injury, and the downregulation of expression of repaired genes accounted for 17.20% 14 days after the injury.ConclusionsA mass of gene expression changes occurs after the optic nerve injury, and the comprehensive view on the gene expression pattern following the optic nerve injury is crucial to discover the mechanism of post-injury reaction and regeneration.(Chin J Ocul Fundus Dis, 2005,21:163-166)
Silicone oil is a stable intraocular tamponade widely used in various vitreoretinal surgeries. However, it can migrate into the anterior chamber for various reasons, leading to complications such as pupillary block glaucoma, corneal endothelial decompensation, and keratopathy. The inferior peripheral iridectomy (later referred to as the Ando iridectomy) can allow the aqueous humor from the posterior segment to drain into the anterior chamber, and this drainage exerts pressure on the silicone oil, pushing it back into the vitreous cavity, thereby effectively addressing the complications. The application of the Ando iridectomy has expanded from aphakic eyes to phakic eyes and pseudophakic eyes in recent years, each with specific indications. The diameter of the Ando iridectomy should be ≥ 2 mm. The incision for the Ando iridectomy should be made at the 6 o'clock position at the iris root, at the lower edge of the silicone oil droplet in the anterior chamber, or in the inferior aqueous humor zone. Postoperatively, the Ando iridectomy may close due to inflammation or blood cell blockage. In such cases, it can be reopened using laser photocoagulation, surgical peripheral iridectomy, or needle puncture to restore its functionality. Currently, there is no standardized protocol for the application of the Ando iridectomy in vitreoretinal surgeries, and this warrants further research.