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 compare the effects of olfactory ensheathing cell (OEC)-containing and pre-degenerated peripheral nerve (PN) transplantation on the axonal regeneration of axotomized retinal ganglion cells (RGC) in adult rats. Methods Twenty-four Sprague-Dawley rats were randomly divided into 4 groups with 6 rats in each group. A segment of the normal (group A) or 10mu;l-OEC-injected (group B) autogenetic sciatic nerve was sutured onto the ocular stump of the left transected optic nerve (ON). In another 2 groups, the removed sciatic nerve was cultured (group C) or co-cultured with OEC (group D) in vitro for 5 days before transplantation. All animals were executed 4 weeks after transplantation, and the number of Fluoro-goldlabeled RGC in each group was counted. Results The averages of regenerating RGC in group B (1481plusmn;268), C (1235plusmn;266) and D (1464plusmn;285) were significantly higher than that in group A (799plusmn;109; P=0.0002, 0.0010 and 0.0003, respectively). No significant difference was found among group B, C and D (P=0.3644, 0.9167 and 0.4344). Conclusion OEC can promote the axonal regeneration of axotomized RGC in fresh PN graft, which doesnprime;t differ much from the effect of the pre-degenerated PN graft. No additive effect of OEC and the pre-degenerated PN graft can be detected. (Chin J Ocul Fundus Dis, 2007, 23: 130-132)
Objective To evaluate the inhibiting effect of adenosine on rat retinal ganglion cells (RGC) death induced by P2X7 and N-methyl-D-aspartate (NMDA) receptor. Methods (1) Long-Evan neonatal rats were back labeled with aminostilbamidine to identify RGC. The viability of RGC affected by P2X7 excitomotor BzATP (50 mu;mol/L), glutamate receptor excitomotor NMDA (100 mu;mol/L) and adenosine (300 mu;mol/L) was detected. (2) RGC from the retinae of unlabeled neonatal rats were cultured in vitro. After labeled with Fura-2 methyl acetate, an intracellular calcium indicator, the effect of BzATP, NMDA and adenosine on intracellular Ca2+ level was detected byCa2+ imaging system. Results Both BzATP (50 mu;mol/L) and NMDA(100 mu;mol/L) could kill about 30% of the RGC. Cell death was prevented by adenosine (300 mu;mol/L) with the cell viability increased from (68.9plusmn;2.3)% and (69.9plusmn;3.2)% to (91.2plusmn;3.5)% (P<0.001) and (102.1plusmn;3.9)% (P<0.001), respectively. BzATP (50 mu;mol/L) led to a large, sustained increase of intracellular Ca2+ concentration to (1183plusmn;109) nmol/L. After the adenosine intervened, Ca2+ concentration increased slightly to (314plusmn;64) nmol/L (P<0.001). Conclusion Adenosine may prevent RGC death and increase of intracellular Ca2+ concentration from P2X7and NMDA receptor stimulation. (Chin J Ocul Fundus Dis, 2007, 23: 133-136)