Objective To observe the inhibition effect of selective cyclooxygenase2 inhibitor(celecoxib)on the experimental choroidal neovascularization(CNV). Methods Thirty 8-10 weeks old healthy male Brown-Norway(BN)rats were randomly divided into the control, laser and celecoxib group,with 10 rats in each group. At the dosage of 50 mg/kg, celecoxib was gavaged twice per day. After 7 days, experimental CNV was induced by Krypon laser on laser group and celecoxib group. Fundus fluorescein angiography (FFA) was performed on days 3, 7,14,21,30 after laser photocoagulation.On days 21 after photocoagulation, 5 rats in each group were sacrificed and the relative thickness of CNV membranes, the expression of COX-2, vascular endothelial growth factor(VEGF) and matrix metalloproteinase-2(MMP-2) were studied by histopathologic or immunohistochemistry examination.Results On days 21 after photocoagulation, the incidence of CNV in the celecoxib group is significantly lower than that in the laser group (chi;2=7.1068,P=0.0077); the relative thickness of the CNV membranes in the celecoxib group is reduced 41.38% compared to the laser group, the difference is statistically significant (t=16.760 0,P=0.0000).COX-2,VEGF and MMP-2 expression in the CNV membrane of celecoxib group were significantly lower than in control group (t=5.710 0,5.840 0, 8.020 0; P=0.000 0); the COX-2, VEGF and MMP-2 expressions in choroid and retina of control group were weak. Conclusion Prophylactic celecoxib can reduce the expression of VEGF and MMP-2 by inhibiting COX-2, and prevent the CNV induced by laser photocoagulation.
ObjectiveTo observe the efficacy of different administration of conbercept on choroidal neovasculature (CNV) in patients with pathological myopia (PM).MethodsA retrospective case-control study. From June 2012 to June 2017, 57 patients (61 eyes) with PM-CNV diagnosed in the Ophthalmology Department of General Hospital of Central Theater Command were included in this study. All patients underwent BCVA, intraocular pressure, refractive index, slit lamp microscope, FFA, OCT examination and axial length (AL) measurement. An international standard vision chart was used in the BCVA test, which was converted to logMAR vision. According to the initial treatment plan, the patients were divided into 1+PRN treatment group (group A) and 3+PRN treatment group (group B), with 27 patients (31 eyes) and 30 patients (30 eyes), respectively. There was no significantly statistical difference in baseline data between the two groups (P>0.05). The eyes was injected with 10 mg/ml of conbercept 0.05 ml (including conbercept 0.5 mg). After completion of initial treatment, on-demand treatment was performed according to repeated treatment standards. The average follow-up time was 30.8 months. The time point for curative effect determination was 24 months after treatment. The frequency and recurrence rate of vitreous cavity injections in the two groups of patients and the changes of BCVA, central macular thickness (CMT), diopter and AL were compared and observed. Continuous variables were compared between groups by independent sample t test. Categorical variables were compared by χ2 test. logMAR BCVA and injection frequency were compared by Wilcoxon rank test. Comparison of CMT before and after treatment was performed by paired t test.ResultsAfter 24 months, the number of intravitreal injections in group A and group B were 3.94±1.88 and 4.83±1.72, respectively, with statistically significant difference (Z=-2.182, P=0.029). After completion of initial treatment, the number of retreatments in group A and group B were 2.94±1.88 and 1.83±1.72, respectively, with significantly statistical different (Z=-2.330, P=0.020). The CNV recurrence rates were 38.71% and 13.33%, respectively, with statistically significant difference (χ2=5.074, P=0.024). Compared with prior treatment, the average BCVA at 1, 3, 6, 12, and 24 months after treatment significantly increased in group A and B (Group A: Z=5.634, 5.367, 5.532, 6.344, 6.135l; P<0.05. Group B: Z=5.809, 5.090, 5.341, 5.939, 8.103; P<0.05). At 1, 3, 6, and 12 months after treatment, there was no statistically significant difference in the average BCVA of the two groups (Z=-0.966, -0.932, -0.523, -1.759; P=0.334, 0.351, 0.601,0.079); the difference was statistically significant at 24 months (Z=-2.525, P=0.012). Compared with CMT before treatment, the difference in the average CMT reduction of the eyes in groups A and B was statistically significant at 1, 3, 6, 12, and 24 months (Group A: t=4.691, 2.624, 2.121, 1.921, 2.237; P<0.05. Group B: t=4.947, 4.554, 5.290, 5.567, 5.314; P<0.05); the average CMT comparison between the two groups was not statistically significant (P=0.457, 0.871, 0.505, 0.333, 0.798). During the follow-up period, there were no ocular complications and systemic adverse reactions.ConclusionsDifferent administration methods for the treatment of PM-CNV by intravitreal injection of conbercept are safe and effective, which can effectively improve BCVA and reduce CMT. Total injection of 3+PRN is more than 1+PRN. However, the injections of retreatment and CNV recurrence rate is lower, and the final follow-up vision is better.
Wet age-related macular degeneration (wAMD) is caused by choroidal neovascularization (CNV), which occurs when the choroidal new capillaries reach the RPE layer and photoreceptor cell layer through the ruptured Bruch membrane, leading to neovascularization bleeding, leakage, and scarring. In view of the important role of VEGF in the development of CNV, targeted therapy with various intraocular anti-VEGF drugs is the first-line treatment for wAMD. However, the efficacy of anti-VEGF drugs in the treatment of wAMD is affected by a variety of factors, and some patients still have problems such as unresponsiveness, drug resistence, tachyphylaxis, long-term repeated injections, and severe adverse effects. It is the direction of future researches to deeply explore the physiological and pathological process of wAMD, find the cause of CNV formation, and seek better therapies.
The therapeutic effect of anti-vascular endothelial growth factor (VEGF) for neovascular age-related macular degeneration (nAMD) was determined by a number of factors. Comprehensive thorough analysis of clinical features, imaging results and treatment response can predict the potential efficacy and possible vision recovery for the patient, and also can optimize the treatment regime to make a personalized therapy plan. Precise medicine with data from genomics, proteomics and metabolomics study will provide more objective and accurate biology basis for individual precise treatment. The future research should focus on comprehensive assessment of factors affecting the efficacy of anti-VEGF therapy, to achieve individualized precise diagnosis and treatment, to improve the therapeutic outcome of nAMD.