Objective To observe the clinical effect of intravenous thrombolytic therapy for central retinal artery occlusion (CRAO) with poor effect after the treatment of arterial thrombolytic therapy. Methods Twenty-four CRAO patients (24 eyes) with poor effect after the treatment of arterial thrombolytic therapy were enrolled in this study. There were 11 males and 13 females. The age was ranged from 35 to 80 years, with the mean age of (56.7±15.6) years. There were 11 right eyes and 13 left eyes. The visual acuity was tested by standard visual acuity chart. The arm-retinal circulation time (A-Rct) and the filling time of retinal artery and its branches (FT) were detected by fluorescein fundus angiography (FFA). The visual acuity was ranged from light sensation to 0.5, with the average of 0.04±0.012. The A-Rct was ranged from 18.0 s to 35.0 s, with the mean of (29.7±5.8) s. The FT was ranged from 4.0 s to 16.0 s, with the mean of (12.9±2.3) s. All patients were treated with urokinase intravenous thrombolytic therapy. The dosage of urokinase was 3000 U/kg, 2 times/d, adding 250 ml of 0.9% sodium chloride intravenous drip, 2 times between 8 - 10 h, and continuous treatment of FFA after 5 days. Comparative analysis was performed on the visual acuity of the patients before and after treatment, and the changes of A-Rct and FT. Results After intravenous thrombolytic therapy, the A-Rct was ranged from 16.0 s to 34.0 s, with the mean of (22.4±5.5) s. Among 24 eyes, the A-Rct was 27.0 - 34.0 s in 4 eyes (16.67%), 18.0 - 26.0 s in 11 eyes (45.83%); 16.0 - 17.0 s in 9 eyes (37.50%). The FT was ranged from 2.4 s to 16.0 s, with the mean of (7.4±2.6) s. Compared with before intravenous thrombolytic therapy, the A-Rct was shortened by 7.3 s and the FT was shortened by 5.5 s with the significant differences (χ2=24.6, 24.9; P<0.01). After intravenous thrombolytic therapy, the visual acuity was ranged from light sensation to 0.6, with the average of 0.08±0.011. There were 1 eye with vision of light perception (4.17%), 8 eyes with hand movement/20 cm (33.33%), 11 eyes with 0.02 - 0.05 (45.83%), 2 eyes with 0.1 - 0.2 (8.33%), 1 eye with 0.5 (4.17%) and 1 eye with 0.6 (4.17%). The visual acuity was improved in 19 eyes (79.17%). The difference of visual acuity before and after intravenous thrombolytic therapy was significant (χ2=7.99, P<0.05). There was no local and systemic adverse effects during and after treatment. Conclusion Intravenous thrombolytic therapy for CRAO with poor effect after the treatment of arterial thrombolytic therapy can further improve the circulation of retinal artery and visual acuity.
Anti-vascular endothelial growth factor (VEGF) drugs, including monoclonal antibodies (such as bevacizumab and ranibizumab) and fusion protein agents (such as aflibercept and conbercept) have been clinically proven to be effective to treat exudative age-related macular degeneration AMD). However, there are still some patients do not or poorly respond to the initial anti-VEGF agents, usually after several injections, ophthalmologists may switch to another anti-VEGF agent. In general, switching of anti-VEGF agent is considered for recurrent AMD, AMD resistance to anti-VEGF treatments. Current switching protocols include the replacement of monoclonal antibodies with fusion protein agents, the replacement of fusion protein agents with monoclonal antibodies, the substitution of one monoclonal antibody with another one, and the replacement of monoclonal antibodies with fusion protein agents and switching back with monoclonal antibodies. However, current researches on the switching of anti-VEGF drugs for exudative AMD are mostly retrospective and single-arm studies, and there are some differences in the results of different studies. Therefore, for patients with exudative AMD who do not respond to or respond poorly to anti-VEGF drugs, the efficacy of switching of anti-VEGF drugs is uncertain right now. Switching of anti-VEGF agents may improve the retinal anatomical outcome of the affected eye but may not necessarily improve visual acuity. Thus it is an option in the clinical practice to treat AMD. To determine the benefits of above mentioned switching regimens, randomized controlled clinical trials with large sample number and long study period will be needed.
Objective To observe the change of diffusion upper limit of macromol ecules through pathological retina and the difference between the layers of retina. Methods Retinal edema was emulated by establishing branch retinal vein occlusion (RVO) model in miniature pig eyes under photodynamic method. Two days later, the retinas of both eyeballs were peeled off. The diffusion test apparatus was designed by ourselves. FITC-dextrans of various molecular weights (4.4, 9.3, 19.6, 38.9, 71.2 and 150 kDa) and Carboxyfluorescein (376 Da) were dissolved in RPMI1640 solutions and diffused through inner or outer surface of retina. The rate of transretinal diffusion was determined with a spectrophotometer. Theoretical maximum size of molecule (MSM) was calculated by extrapolating the trend-linear relationship with the diffusion rate. In separate experiments to determine the sites of barrier to diffusion, FITC-dextrans were applied to either the inner or outer retinal surface, processed as frozen sections, and viewed with a fluores cence microscope. Results FITC-dextrans applying to inner retinal surface, 4.4 kDa dextrans were largely blocked by inner nuclear layer (INL); 19.6,71.2 kDa dextrans were blocked by the nerve fiber layer (NFL) and inner plexiform layer; 15.0 kDa dextrans were blocked by NFL. FITC-dextrans applying to outer retinal surface, most dextrans with various molecular weights were blocked before outer nuclear layer (ONL). No matter applying to the inner or outer surface, Carboxyfluore scein can diffuse through the whole retina and aggregate at INL and ONL. After RVO, the inner part of retina became edema and cystoid, loosing the barrier function. Compared with the normal retina, the MSM in RVO tissues increased (6.5plusmn;0 39nm Vs 6.18plusmn;0.54nm, t=4.143, P=0.0001). Conclusions A fter RVO, the barrier function of inner part of retinal is destroyed and the upper limit of diffusion macromolecule size increased, which is nevertheless limited. ONL acts as bottle-neck barriers to diffusion, if the outer part of retina is damaged, the change of the diffusion upper limit will be prominent. (Chin J Ocul Fundus Dis,2008,24:197-201)
ObjectiveTo seek the evidencebased medicine (EBM) evidences of curative effects of intravitreous injection with triamcinolone acetonide (TA) for macular edema.MethodsAll articles of intravitreous injection TA for macular edema published in English or Chinese were picked up from databases of MEDLINE and CNKI and then evaluated according to EBM standard. The data in accord with research standard were selected by using excluding and including criteria, and classified according to the appraisal standard of clinical therapeutic documents. ResultsIn the selected papers, none in gradeⅠevidence; 1 in gradeⅡevidence; 7 in grade Ⅲ evidence; 24 in grade Ⅳ evidence; and 19 in gradeⅤevidence. Forty-two papers reported that intravitreous injection with TA had significant effect for macular edema within 3 months, and the improvement of visual acuity was recorded in these papers. Regression of macular edema was recorded in 23 papers. Among 20 papers, side-effect was found in 93 eyes (31.41%) and the serious sideeffect in 4 eyes (1.35%).ConclusionsIntravitreous injection with TA has some curative effects for macular edema in short term, but the quality of current study has not been encouraging. There are no grade I document and lack of the study of validity in long term and essentiality and validity of retreatment. The special attention should be payed on the increasing persistency of efficacy and preventing the serious side-effects in the future investigation.(Chin J Ocul Fundus Dis, 2005,21:220-223)
Objective To investigate the effects of celecoxib-poly lactide-co-glycolide microparticles (CEL-PLGA-MS) on rat retina after intravitreal injection. Methods A total of 32 male Brown Norway rats were randomly divided into CEL-PLGA-MS group and celecoxib group, 16 rats in each group. The rats in CEL-PLGA-MS group were divided into four dosage group, four rats in each group, which received intravitreal injection of PLGA with celecoxib at the concentration of 40, 80, 160, 320 mu;mol/L, respectively. The rats in celecoxib group were divided into four dosage group, four rats in each group, which received intravitreal injection of celecoxib at the concentration of 40, 80, 160, 320 mu;mol/L, respectively. Phosphate buffer solution (PBS) was injected in two rats as PBS control group. Two rats as normal control group received no treatment. The difference of retinal thickness among groups was measured by optical coherence tomography (OCT). The morphological and histological change of retina was evaluated under light microscope and transmission electron microscope. Results There was no difference of retinal thickness between normal control group and PBS control group (F=0.12,P>0.05). At the first week after injection, the retinal thickness of CEL-PLGA-MS group and celecoxib group were thicker than that in normal control group and PBS control group (F=9.62, 46.13;P<0.01). The retinal thickness of celecoxib group was thicker than that in CEL-PLGA-MS group (F=165.15,P<0.01). The retinal thickness was estimated equal among 40, 80, 320 mu;mol/L dosage groups in CEL-PLGA-MS group (F=4.79,P<0.01). The retinal thickness of 160, 320 mu;mol/L dosage group were thicker than that in 40, 80 mu;mol/L dosage group in celecoxib group (F=28.10,P<0.01). At the second week after injection, there was no difference of retinal thickness between CEL-PLGA-MS and celecoxib group (F=3.79,P>0.05); the retinal thickness of CEL-PLGA-MS and celecoxib group became thinner gradually compare to the first week after injection (F=7.28, 103.99; P<0.01). At the fourth week after injection, the retinal thickness of celecoxib group was thicker than that in CEL-PLGA-MS group (F=19.11,P<0.01). The retinal thickness of CEL-PLGA-MS group was approximately the same to normal control group and PBS control group (F=2.02,P>0.05). The retinal thickness of celecoxib group was thicker than that in normal control group and PBS control group. No considerable abnormality of the retina was seen by light microscope and the retinal thickness corresponded with the values measured by OCT at the first week after injection. The abnormal structures of the retina were seen in 160, 320 mu;mol/L dosage group of celecoxib group and inner changed evidently by the transmission electron microscope. Disordered arrangement of microfilaments, dilated microtubule and some mitochondria vacuolation were observed in 320mu;mol/L dosage group of celecoxib group. Others changed slightly. Conclusions CEL-PLGA-MS has less toxicity on the retina than free-celecoxib after intravitreal injection. The safety of intravitreal injection with CEL-PLGA-MS is better than celecoxib.
ObjectiveTo compare the clinical effects of urokinase thrombolytic therapy for optic artery occlusion (OAO) and retinal artery occlusion (RAO) caused by facial microinjection with hyaluronic acid and spontaneous RAO.MethodsFrom January 2014 to February 2018, 22 eyes of 22 patients with OAO and RAO caused by facial microinjection of hyaluronic acid who received treatment in Xi'an Fourth Hospital were enrolled in this retrospective study (hyaluronic acid group). Twenty-two eyes of 22 patients with spontaneous RAO were selected as the control group. The BCVA examination was performed using the international standard visual acuity chart, which was converted into logMAR visual acuity. FFA was used to measure arm-retinal circulation time (A-Rct) and filling time of retinal artery and its branches (FT). Meanwhile, MRI examination was performed. There were significant differences in age and FT between the two groups (t=14.840, 3.263; P=0.000, 0.003). The differecens of logMAR visual acuity, onset time and A-Rct were not statistically significant between the two groups (t=0.461, 0.107, 1.101; P=0.647, 0.915, 0.277). All patients underwent urokinase thrombolysis after exclusion of thrombolytic therapy. Among the patients in the hyaluronic acid group and control group, there were 6 patients of retrograde ophthalmic thrombolysis via the superior pulchlear artery, 6 patients of retrograde ophthalmic thrombolysis via the internal carotid artery, and 10 patients of intravenous thrombolysis. FFA was reviewed 24 h after treatment, and A-Rct and FT were recorded. Visual acuity was reviewed 30 days after treatment. The occurrence of adverse reactions during and after treatment were observed. The changes of logMAR visual acuity, A-Rct and FT before and after treatment were compared between the two groups using t-test.ResultsAt 24 h after treatment, the A-Rct and FT of the hyaluronic acid group were 21.05±3.42 s and 5.05±2.52 s, which were significantly shorter than before treatment (t=4.569, 2.730; P=0.000, 0.000); the A-Rct and FT in the control group were 19.55±4.14 s and 2.55±0.91 s, which were significantly shorter than before treatment (t=4.114, 7.601; P=0.000, 0.000). There was no significant difference in A-Rct between the two groups at 24 h after treatment (t=1.311, P=0.197). The FT difference was statistically significant between the two groups at 24 h after treatment (t=4.382, P=0.000). There was no significant difference in the shortening time of A-Rct and FT between the two groups (t=0.330, 0.510; P=0.743, 0.613). At 30 days after treatment, the logMAR visual acuity in the hyaluronic acid group and the control group were 0.62±0.32 and 0.43±0.17, which were significantly higher than those before treatment (t=2.289, 5.169; P=0.029, 0.000). The difference of logMAR visual acuity between the two groups after treatment was statistically significant (t=2.872, P=0.008). The difference in logMAR visual acuity before and after treatment between the two groups was statistically significant (t=2.239, P=0.025). No ocular or systemic adverse reactions occurred during or after treatment in all patients. ConclusionsUrokinase thrombolytic therapy for OAO and RAO caused by facial microinjection with hyaluronic acid and spontaneous RAO is safe and effective, with shortening A-Rct, FT and improving visual acuity. However, the improvement of visual acuity after treatment of OAO and RAO caused by facial microinjection with hyaluronic acid is worse than that of spontaneous RAO.
Diabetic macular edema (DME) is a common ocular complication of diabetes patients. It mainly involve macular which is closely related with visual function, thus DME is one of the major reasons causing visual impairment or blindness for diabetes patients. How to reduce the visual damage of DME is always a big challenge in the ophthalmic practice. In the past three decades, there are tremendous developments in DME treatments, from laser photocoagulation, antiinflammation drugs to antivascular endothelial growth factor therapy. However, the mechanism of DME development is not yet completely clear; every existing treatment has its own advantages and weaknesses. Therefore DME treatment still challenges us to explore further to reduce the DME damages.
Retinoblastoma (RB) is the most common intraocular malignant tumor in children. With advanced clinical technologies there are more and more methods available to treat retinoblastoma, and make it is possible to delivery individualized protocol combined traditional treatments with modern regimen to patients now. In order to improve the survival rate and the life quality of RB patients in China, it is very important to make a suitable system of standardized therapy based on results from developed countries and health policies of our own country.
ObjectiveTo observe the clinical efficacy of intravitreal Conbercept on idiopathic choroidal neovascularization (ICNV). MethodsThis is an open and prospective study without control trial. Twelve eyes from 11 patients (7 females and 4 males) with ICNV diagnosed by best corrected visual acuity (BCVA), non-contact tonometer, ophthalmoscope, fundus photography, optical coherence tomography (OCT) and fundus fluorescein angiography (FFA) were enrolled in this study. All affected eyes were treated with intravitreal Conbercept 0.05 ml (10 mg/ml) and received an average of (1.91±1.04) injections. The initial average letters of Early Treatment Diabetic Retinopathy Study (ETDRS) chart acuity were 61.73±14.58, range from 25 to 77. The patients were followed up for 6 to 9 months.The initial average central retinal thickness (CRT) was (330.73±47.79)μm, range from 290 to 467 μm. Best-corrected visual acuity (BCVA), OCT and ophthalmoscope examination were assessed monthly. ResultsDuring the 1, 3, 6 months after treatment, themean BCVA were all improved with statistically significant difference (t=2.68, 3.80, 3.65; P < 0.05). At 1 month later after treatment, the mean BCVA was obviously improved in 1 eye (9.09%), improved in 8 eyes (72.73%), stable in 1 eye (9.09%), decreased in 1 eye (9.09%). At 6 month later after treatment, the mean BCVA was obviously improved in 3 eyes (27.27%), improved in 6 eyes (54.55%), stable in 1 eye (9.09%), decreased in 1 eye (9.09%).During the 1, 3, 6 months after treatment, the mean CRT were all decreased with statistically significant difference(t=2.44, 3.78, 4.12; P < 0.05).At latest follow up, the leakage in macula lutea disappeared in 6 eyes(58.33%), decreased in 11 eyes (25%)and increased in 3 eyes (16.67%). There were no systemic or ocular serious side effects during the follow up. ConclusionIntravitreal Conbercept for ICNV showed CNV regression, retinal thickness reduction, visual acuity improvement and safety.
Objective To observe the effect of resveratrol on multidrug resistance (MDR) in human retinoblastoma cells treated. Methods RB cells in logarithmic growth phase were divided into experimental group and control group. RB cells in experimental group were cultured with different concentrations of resveratrol (6.25, 12.50, 25.00, 50.00, 100.00 mu;mol/L) for 24 and 48 hours. The proliferation (absorbance value) was assayed using methyl thiazolyl tetrazolium (MTT). RB cells were cultured with 50.00 mu;mol/L resveratrol for 48 hours. The expressions of MDR-1, cyclooxygenase-2 (COX-2)、multidrug resistance-associated protein-1 (MRP-1), glutathione-S-transferases-pi; (GST-pi;) were determined by reverse transcription-polymerase chain reaction (RT-PCR) and Western blot. The RB cells of the control group were cultured with 0.5% dimethyl sulfoxide. Results Compared with the control group, the absorbance value decreased in experimental groups (6.25, 12.50, 25.00, 50.00 mu;mol/L) in a dose dependent manner (F=4.782,P<0.05). The difference of absorbance value between 50.00 and 100.00 mu;mol/L experimental groups was not significant (F=6.351,P>0.05). Compared with the control group, the mRNA (t=9.170, 5.758, 4.152, 4.638) and protein (t=3.848, 5.955, 4.541, 3.514) expression levels of MDR-1, MRP1, COX-2, and GST-pi; decreased in the experimental group (P<0.05). Conclusion Resveratrol can down-regulate the expression of MDR in RB cells.