Objective To observe the protective effect on retinal ganglion cells (RGC) and the safety of intravitreal injected acteoside in rats. Methods A total of 50 male Sprague Dawley rats with the weight of 190-210 g were used in this study. Fifteen rats were used for safety experiment of intravitreal injection of acteoside. The rats were divided into group A, B, C, control group and blank group, three rats in each group. The rats in group A, B and C were received intravitreal injection of 5 mu;l acteoside at the concentration of 1, 2, and 5 mg/ml, respectively. Phosphate buffer solution (PBS) was injected in rats of control group. No treatment was performed for blank group. The retinal structure was examined by hematoxylin-eosin (HE) staining of retinal frozen sections at one, two and three weeks after injection. The retinal ultrastructure was examined by ultrathin section under transmission electron microscope at one and three weeks after injection. Others 35 rats were used for experiment of protective effect of acteoside on RGC. The rats were divided into operation group A and B (n=8), sham operation group C and D (n=8), and blank group (n=3). The optic nerve of rats in operation group was clamped for 10 seconds after optic nerve exposure, while the optic nerve of rats in sham operation group was exposed only. The rats in operation group A and B were received intravitreal injection with 5 mu;l acteoside (1 mg/ml) and 5 mu;l PBS respectively. The rats in sham operation group C and D were received intravitreal injection with 1 mu;l acteoside (1 mg/ml) and 1 mu;l PBS respectively. No treatment was performed for blank group. The retinal structure was examined by HE staining of retinal frozen sections at one, two and four weeks after injection. Immunohistochemistry was used to measure the expression of growth associated protein 43 (GAP-43). RGC apoptosis was assessed by the terminal deoxynucleotidyl transferase mediated dUTPbiotin nickend labelling (TUNEL) method. Software of SPSS 13.0 was used for the data statistical analysis in this study. Results In the safety experiment of intravitreal injected acteoside, there was no abnormity of cornea, anterior chamber, lens, vitreous cavity and retina after injection. At one, two and three weeks after injection, the retina structure was normal without significant apoptosis, necrosis and inflammatory cell infiltration. The ganglion cell layer showed slightly edema; there was no obvious change of retinal ultrastructure after injection of acteoside with 5 mg/ml and 2 mg/ml, but slight change with the format of 1 mg/ml. Transmission electron microscopy showed that intravitreal injection of 5 mu;l acteoside at the concentration of 2 or 5 mg/ml can induce significant changes of micro-structures of retina, while injections at 1mg/ml can only induce minor changes.In the experiment of protective effect of acteoside on RGC, light microscope revealed that the cell showed typical changes of apoptosis in operation group, but not in sham operation group and blank group. At the first and second week after injection, compared with the sham operation group and blank group, the RGC number was decreased in operation group. The difference of RGC numbers between operation group A and B was statistically different (F=26.206,P<0.05). The RGC numbers in operation group continues to decrease at the fourth week after injection, there was obvious difference compared with the first and second week after injection (F=17.364,P<0.05), but there was no difference of RGC numbers among sham operation intragroup and between sham operation group and blank group at all the time points. Immunohistochemistry showed that at the first week after injection, the integrated absorbance (IA) value in operation group was higher than that in other groups (F=33.466,P<0.05); there was no difference of IA value between operation group A and B. At the second week after injection,IA value in operation group A had slightly declined, but higher than that in operation group B (F=14.391,P<0.05). At the fourth week after injection,IA value in operation group A declined further, but also higher than that in other groups (F=4.178,P<0.05). TUNEL showed that on the first week after injection, RGC apoptosis rate in operation group was increased than that in other groups (F=15.365,P<0.05). At the second week after injection, RGC apoptosis rate in operation group was decreased, and it in operation group A was lower than that in operation group B (F=15.365,P<0.05). At the fourth week after injection, RGC apoptosis rate in operation group was decreased obviously, there was no difference compared with other groups (F=2.057,P>0.05). There was no difference of RGC apoptosis rate between sham operation group and blank group at all the time points. Conclusion Intravitreal injection of 5 mu;l acteoside (1 mg/ml) is safe for rat retina, and can upregulate GAP-43 expression and inhibit RGC apoptosis in optic nerve crush rats.
Objective To investigate the protective effects of ginkgo biloba extract (EGb) 761 on retinal ganglion cells (RGC) in rats,and to establish a method to define the rat RGC using fluorogold as a fluorescence dye. Methods RGC of 12-20 day-old SpragueDawley rats were labeled by injecting fluorogold into superior colliculus. The eyeball enucleation was performed 6 days later. Retinal stretched preparation was obtained from one eye to observe the label result under fluorescence microscope, and the retina from the other eye was detached to make the cell suspension to observe the configuration of stained RGC under the contrast fluorescence microscope. The cell suspension was divided into the control group and Egb761 groups with the concentration of 0.03%,0.10%, 0.30%, 1.00%, and 3.00%. Trypan blue dye was used to evaluate cells viability and the survival rate of the large retinal ganglion cells was calculated. Results The sign of the RGC was clear after labeled by fluorogold. The characteristics of large RGC were obvious. After detachment, large RGC died quickly in the cell suspension and the fluorescence disappeared. The result of Trypan blue staining indicated that large RGC died rapidly in the cell suspension. Large RGC in EGb761 group showed significantly better survival rates than that in control group at different time sites (Plt;0.01) in a dose-dependent manner (Plt;0.01). Conclusions EGb761 has a significant protective effect on large RGC cultivated in vitro, and retrolable method to identify RGC is feasible.
Objective:To observe the protective effect of ginkgo bilo ba extrac t (EGb 761), a free radical scavenger, on the photoreceptor cells after lighti nduced retinal damage. Methods:Seventytwo female SpragueDa wley (SD) rats we re randomly divided into 4 groups: normal control group, lightinduced retinal da m age model group, model+physiological saline group, and model+EGb 761 group, with 18 rats in each group. All of the rats except the ones in the control group were exposed to white light at (2740plusmn;120) lx for 6 hours after the dark adap tation for 24 hours to set up the lightinduced retinal damage model. Rats in m o del + physiological saline group and model+EGb 761 group were intraperitoneall y injected daily with physiological saline and 0.35% EGb 761 (100 mg/kg), respec tively 7 days before and 14 days after the light exposure. Apoptosis of photorec eptor cells was detected 4 days after light exposure; 7 and 14 days after light exposure, histopathological examination was performed and the layer number of ou ter nuclear layers (ONL) on the superior and inferior retina was counted. Results:Four days after light exposure, the apoptosis of photorecep tor cells was fou nd on ONL in model, model+ physiological saline and model+EGb 761 group, and w as obviously less in model + EGb 761 group than in model and model+physiologic al saline group. Seven days after light exposure, the layers of ONL on the super ior retina were 3 to 4 in model and model+physiological saline group, and 7 to 8 in model+EGb 761 group; the mean of the layer number of ONL in model+EGb 761 group (6.92plusmn;0.82) was less than that in normal control group (8.40plusmn;0.95) (t=-1.416, P<0.05), but significantly more than that in model (5.96 plusmn;1.36 ) and model+physiological saline group (5.90plusmn;1.40)(t=1.024, 1.084; P<0.05). Fourteen days after light exposure, the layers of ONL on the superior retina were 0 to 1 in model and model+physiological saline group, and 3 to 4 i n model+EGb 761 group. The mean of the layer number of ONL in model+EGb 761 group (5.5 2plusmn;1.06) was significantly more than that in model (3.44plusmn;2.15) and model + physiological saline group (3.37plusmn;1.91) (t=2.082, 2.146, P<0.05). Conclusion:EGb 761 can partially inhibit the apoptosis of pho toreceptor cells, thus exert protective effect on photoreceptor cells.
Objective To explore the effects of drugs on functions of mitochondria in retinal nerve cells, and to lay a foundation of the investigation of drug protection for retinal nerve cells. Methods Cultivation of the retinal nerve cells of 8 eyes of neonatal calves was performed. The changes of fluorescent density of the mitochondria of cultured cells labeled by dye rhodamine 123 (Rh123) before and after the activation of the medicines, including ferulic acid (FA), arginine, glycine,taurine, vitamine E and brain derived neurotrophic factor( BDNF) respectively, were detected by laser-scanning confocal microscopy. Results FA with the concentration of 500 μg/ml led the diphasic variation of the fluorescent intensity of mitochondria. After scanning for 60.772 seconds when treated with FA firstly, the fluorescent intensity decreased rapidly (from 45.425±4.153 to 22.135±5.293); while after 112.774 seconds when treated secondly, the in tensity increased obviously (from 19.655±4.383 to 28.247±4.764), and after 168.773 seconds when treated thirdly the intensity still increased. After scanning for 56.457 seconds when treated with vitamin E (12.5 mg/ml), the fluorescent in tensity increased obviously (from 88.255±5.039 to 111.273±4.529), which suggested that vitamin E with the concentration of 12.5 mg/ml strengthen the fluorescent intensity. After scanning for 58.147 and 134.148 seconds when treated with BDNF(50 ng/ml) respectively, the fluorescent intensity increased obviously (from 69.115±5.038 to 77.225±5.131) which suggested that BDNF with the concent ration of 50 ng/ml led the increase of the fluorescent intensity. Glycine (2.5 mg/ml) and arginine(30 mg/ml) didn’t affect the fluorescent intensity of mitochondria, and taurine (6.25 mg/ml) caused the appreciable decrease of the fluorescent intensity . Conclusion FA, BDNF and vitamin E may promote the metabolism of retinal nerve cells via the path of mitochondria, while amino acids may adjust the activation of retinal nerve cells through other ways. (Chin J Ocul Fundus Dis,2004,20:229-232)
Objective To investigate the influnce of L-arginine (L-Arg) and L-nitro-arginine-methyl-ester(L-NAME) to purified retinal ganglion cells(RGCs) apoptosis of rats cultured in different consistencies of L-Arg and L-NAME. Method RGCs from Sprague Dawley (SD) neonatal rats(postnatal 1~5 day) were cultured in assimilative culture solution in vitro and RGCs were purified by Thy1.1 with sheep anti rat FITC monoclonal antibody. RGCs were cultured in different consistencies of L-Arg and L-NAME: 1×10-6, 1×10-5,1×10-4, 1×10-3, 1×10-2 and 1×10-1 mol/L for 24 hours and 48 hours, respectively. The changes of bcl-2, bax and p53 mRNA in RGCs in different consistencies of L-Arg and L-NAME were demonstrated qualitatively and quantitatively by in situ hybridization, and their apoptosis were detected by terminal deoxynucleotidyl transferase mediated dUTP nick end labeling(TUNEL) method, respectively. Results After 24 hours in vitro, the purification rate of RGCs in the experiment arrived at 97 %. After 48 hours, there were a few apoptotic cells expression in the control group. Apoptotic cells expression in L-Arg≥1×10-3 mol/L and L-NAME≥1×10-1 mol/L groups increased that had a significant difference with the control group (Plt;0.05). In the group of L-Arg≥1×10-3 mol/L and L-NAME≥1×10-1 mol/L, the expression of bcl-2 mRNA in RGCs became weaker and weaker as the consistencies were increased, but the expression of bax and p53 mRNA in RGCs became higher and higher and had a significant difference with control group (Plt;0.05). Conclusion Lower concentration of L-Arg can promote the growth of purified RGCs in vitro and higher concentration of L-Arg can promote the apoptosis of RGCs. (Chin J Ocul Fundus Dis, 2002, 18: 137-139)