Objective To observe the clinical features and outcomes of vitrectomy for diabetic retinopathy (DR) with central retinal vein occlusion (CRVO) in type 2 diabetes mellitus (T2DM). Methods A total of 192 patients (241 eyes) with proliferative DR (PDR) who underwent vitrectomy were enrolled in this study. All the patients were diagnosed as vitreous hemorrhage (VH) because of suddenly decreased vision. There were 93 eyes with tractional retinal detachment (TRD) and six eyes with neovascularization of iris (NVI). The patients were divided into PDR with CRVO group (group A, 41 eyes) and PDR group (group B, 200 eyes) according to the results of fundus examination. All patients received vitrectomy with silicone oil and C3F8 gas tamponade. There were 138 eyes with silicone oil tamponade which including 30 eyes in group A and 108 eyes in group B. The difference of number in silicone oil-filled eyes in two groups was statistically significant (chi;2=5.110,P<0.05). There were 38 eyes with C3F8 gas tamponade which including six eyes in group A and 32 eyes in group B. There was no difference in C3F8 gas-filled eyes numbers in two groups (chi;2=0.048, P>0.05). The follow-up ranged from one to 60 months, with the mean of (28.69plusmn;17.28) months. The corrected vision, retinal reattachment, persisting macular edema (ME), neovascular glaucoma (NVG) and repeated VH after surgery were comparatively analyzed. Results Of 241 eyes, there were 41 eyes (17.0%) with CRVO. Before surgery, the differences of corrected vision (Z=-0.138), intraocular pressure (t=0.966), whether there was TRD or not (chi;2=0.412), whether underwent panretinal photocoagulation or not (chi;2=1.416) were not statistically significant (P>0.05), but the difference of whether NVI were present or not was statistically significant (chi;2=31.724,P<0.05) between two groups. After surgery, the corrected vision improved in both two groups (Z=2.319, 4.589; P<0.05). There was no difference of corrected vision after surgery between two groups (Z=0.782,P>0.05). Postoperative complications occurred in 94 eyes, including 26 eyes in group A and 68 eyes in group B. The differences of incidence of reoperation (chi;2=0.498), retinal reattachment (chi;2=0.818), persisting ME (chi;2=2.722) between two groups after surgery were not statistically significant (P>0.05). The incidence of repeated VH (chi;2=5.737) and NVG (chi;2=6.604) in group A were higher than those in group B (P<0.05). Conclusions CRVO is commonly found to coexist with DR in T2DM patients with VH. Combined with CRVO patients are more likely to suffer NVI. Vitrectomy can improve the visual function in PDR with CRVO patients.
Objective To evaluate the therapeutic effect of laser-induced chorioretinal venous anastomosis on macular edema of non-ischemic retinal vein occlusion. Methods Thirty-seven eyes of 37 cases of non-ischemic retinal vein occlusion received the treatment of laserinduced chorioretinal venous anastomosis and were followed up for 6~12 months. All affected eyes underwent the clinical examinations of visual acuity, ocular fundus photography, fundus fluoreceine angoigraphy (FFA) and light sensitivity of central 5 degree of the retina, and the pre- and post-operative clinical materials were analyzed. Results Successful chorioretinal venous anastomosis was formed in 18 eyes (48.6%) within 2 months after laser photocoaglation, with the mean best improved corrected visual acuity of (4.25±0.46) lines, while the mean best corrected visual acuity of the other 19 eyes with unsuccessful anastomosis decreased (0.20±0.54) lines(P<0.001). The light sensitivity of central 5 degree of the 18 eyes with successful anastomosis improved(P<0.001), with resolution of macular edema in 16 eyes, although cystoid macular edema in 2 eyes remained no change. The light sensitivity of central 5 degree of the 19 eyes with unsuccessful anastomosis have decreased(P<0.05), with aggrevation of the macular edema. Conclusion Successful laser-induced chorioretinal anastomosis can resolute the macular edema caused by retinal vein occlusion, especially for diffused macular edema caused by early retinal vein occlusion. (Chin J Ocul Fundus Dis,2002,18:10-12)
ObjectiveTo observe the alterations of microvascular structure in patients with macular edema (ME) associated with branch retinal vein occlusion (BRVO) before and after anti-VEGF drug therapy.MethodsA retrospective case study. Thirty-two eyes of 32 patients with unilateral BRVO-ME at Department of Ophthalmology in Beijing Hospital during November 2016 to June 2018 were enrolled in this study. There were 14 males (14 eyes) and 18 females (18 eyes), with the mean age of 57.81±10.58 years, and the mean course of the disease of 12.13±7.13 d. The affected eyes was defined as the eyes with BRVO-ME. All the affected eyes received intravitreal anti-VEGF drug injections (3+PRN). BCVA and OCT angiography (OCTA) were performed on the BRVO and fellow eyes before and after intravitreal anti-VEGF drug injections. The scanning region in the macular area was 3 mm×3 mm. Macular blood flow density in the superficial capillary plexus (SCP) and deep capillary plexus (DCP), macular hemodynamics parameters [foveal avascular area (FAZ) area, perimeter (PERIM), acircularity index (AI) and vessel density within a 300um width ring surrounding the FAZ (FD-300)] and central retinal thickness (CRT) were measured in all eyes. Paired samples t-test and Univariate Linear Regression were used in this study.ResultsComparing with fellow eyes, the mean macular blood flow density measured in the entire scan was lower in BRVO-ME eyes in the SCP (t=6.589, P=0.000) and DCP (t=9.753, P=0.000), PERIM (t=4.054, P=0.000) ), AI enlarged in BRVO-ME eyes (t=4.988, P=0.000), FD-300 was lower in BRVO-ME eyes (t=2.963, P=0.006), FAZ area enlarged in BRVO-ME eyes (t=0.928, P=0.361). The blood flow density in the DCP was the parameter most significantly correlated with BCVA and FAZ area (r=0.462, −0.387;P< .05). After 3 intravitreal injections of anti-VEGF drug, the CRT and FD-300 decreased, BCVA increased (t=9.865, 3.256, −10.573; P<0.05), PERIM and AI was not changed significantly (t=0.520, 2.004; P>0.05). The blood flow density in the SCP decreased (t=2.814, P<0.05), but the blood flow density in the DCP was not changed significantly (t=0.661, P=0.514). Contrarily, comparing with after 1 anti-VEGF drug injection, the blood flow density in the DCP increased after 2 anti-VEGF drug injections (t=3.132, P<0.05). FAZ area enlarged in BRVO-ME eyes (t=5.340, P<0.001). Comparing with last anti-VEGF drug injection, FAZ area enlarged after every anti-VEGF drug injection (t=2.907, 3.742, 2.203; P<0.05).ConclusionsIn BRVO-ME eyes, the blood flow density in the SCP and DCP are decreased. The blood flow density in the DCP is positively correlated with BCVA and negatively correlated with FAZ area. After anti-VEGF drug therapy, the blood flow density is decreased in the SCP and increased in the DCP, FAZ area enlarged gradually, PERIM and AI are not changed significantly.
ObjectiveTo investigate the effects and safety of intravitreous injection of Conbercept combined with laser photocoagulation for macular edema secondary to branch retinal vein occlusion. MethodsAll subjects were assigned randomly to 3 groups:intravitreal Conbercept combined with laser photocoagulation group (CL group), intravitreal triamcinolone combined with laser photocoagulation group (TL group), and photocoagulation group (L group). The best-corrected visual acuity (BCVA), central macular thickness (CMT), fundus oculi and fundus fluorescein angiography (FFA), intraocular pressure (IOP), slit lamp were observed before and 1 day, 1 week, 1 month, 3 months after treatment. The changes of post-treatment BCVA and CMT in pre-therapy and post-treatment were compared, and related complications were recorded. ResultsThere were significant differences of BCVA (χ2=9.754, 12.430, 17.424, 13.189) and CMT (F=10.614, 4.099, 4.927, 8.99) between 3 groups in post-treatment 1 day, 1 week, 1 month and 3 months. The numbers of subjects of improving and stabilizing BCVA in CL group were remarkably more than that in L group in every post-treatment follow-up time (P < 0.01), whereas the CMTs in CL group were significantly less than that in L group in every post-treatment follow-up time (P < 0.05). The CMTs in post-treatment 1 day, 1 week, 1 month, 3 months were thinner than that in pretreatment in CL group and TL group (P < 0.05). Meanwhile, there was no significant difference (P > 0.05)between any two CMTs in post-treatment 1 day, 1 week, 1 month and 3 months in CL group. Yet, the CMT in post-treatment 3 months was thicker than those in post-treatment 1 day, 1 week and 1 month in TL group(P < 0.05). And there was no significant difference(P > 0.05)between any two CMTs in post-treatment 1 day, 1 week and 1 month in TL group. There was no conspicuous difference in CMTs(P > 0.05)between in CL group and in TL group in every viewing time, except for that in post-treatment 3 months(P < 0.05). There was only 1 case of intraocular hypertension in post-treatment in TL group. ConclusionsIntravitreous injection of Conbercept combined with laser photocoagulation for macular edema secondary to BRVO is effective, safe, and superior to laser photocoagulation only. Also it had a longer effective duration and less complications than intravitreal triamcinolone combined with laser photocoagulation.
Objective To evaluate the effectiveness of repeated intravitreal conbercept injection in patients with macular edema (ME) of retinal vein occlusion (RVO), guided by optic coherence tomography (OCT). Methods It is a retrospective case study. Forty patients (40 eyes) diagnosed as ME secondary to RVO were enrolled in this study. There were 19 males (19 eyes) and 21 females (21 eyes), with the mean age of (53.58±13.19) years and the mean course of 1.5 months. The best corrected visual acuity (BCVA), indirect ophthalmoscopy, fundus fluorescein angiography (FFA) and OCT were performed. The mean baseline of BCVA, central macular thickness (CMT) were 0.25±0.18 and (509.48±170.13) μm respectively. All the patients were treated with 10.00 mg/ml conbercept 0.05 ml (including conbercept 0.5 mg). Follow-up of these patients was 1 to 6 months after treatments, the BCVA, fundus manifestations, OCT were retrospectively observed by every month, the FFA was retrospectively observed by every 3 months. When there was retinal edema or CMT ≥50 μm by OCT during follow-up, those patients were retreated with intravitreal conbercept injection. The changes of the BCVA, CMT were evaluated before and after treatment. Meanwhile, complications in eyes related to medicine and treatment methods were evaluated too. Results At the 6 months, the BCVA was improved (increase≥2 lines) in 25 eyes (62.50%), stabilized (±1 line) in 13 eyes (32.50%) and decreased 2 lines in 2 eyes (5.00%). Retinal hemorrhage and exudates were absorbed in most patients. FFA showed no fluorescein leakage in 11 eyes (27.50%), minor fluorescein leakage in 26 eyes (65.00%), and retinal capillary non-perfusion in 3 eyes (7.50%). OCT showed absorption of the subretinal fluid. The mean CMT were (235.20±100.44) μm at 6 months. Intravitreal injection of conbercept was applied for 4 times in 8 eyes (20.00%), 3 times for 18 eyes (45.00%), and 2 times for 14 eyes (35.00%). The mean number of intravitreal injection was 2.85 times. There were no ocular or systemic adverse events observed in all patients. Conclusion Intravitreal conbercept injection is an efficacy and safe treatment for the patients with ME of RVO guided by OCT. It can stabilize and improve the visual acuity.
Macular edema is a common cause of visual loss in patients with retinal vascular diseases represented by diabetic retinopathy and retinal vein occlusion. Laser photocoagulation has been the main treatment for this kind of diseases for decades. With the advent of antagonist of vascular endothelial growth factor and dexamethasone implant, diabetic macular edema and macular edema secondary to retinal vein occlusion have been well controlled; the use of laser therapy is decreasing. However, considering possible risks and complications, lack of extended inspection of efficacy and safety of intravitreal pharmacotherapy, laser therapy cannot be replaced by now. Therefore, the efficacy and safety of laser therapy will improve by sober realization of role of photocoagulation and proper selection of treatment indication.
Pharmaceutical therapy, including anti-vascular endothelial growth factor treatment and intravitreal corticosteroids, is the most common treatment for branch retinal vein occlusion (BRVO) and its complications, however there are confusing ideas about the protocol, patient selection, timing and endpoint of this treatment. The disease is easy to relapse with these drugs therapy. Collateral vessel formation was found in patients receiving intravitreal injection of ranibizumab or triamcinolone for BRVO and secondary macular edema. The mechanism of collateral vessel formation has not been carefully investigated. In the past thrombolysis, arteriovenous fasciostomy and laser choroidal retinal vascular anastomosis were used to reconstruct the retinal circulation, but their rationality, effectiveness and safety need to be further were studied. In recent years, because of the key technology is still immature, the artificial vascular bypass surgery experiment is not yet practical, but provides us a new idea worth looking forward to for the treatment of BRVO.
ObjectivesTo evaluate the therapeutic effect of argon laser photocoagulation combined with intravitreous injection of triamcinolone acetonide (TA) on ischemic central retinal vein occlusion (CRVO).MethodsArgon laser photocoagulation combined with intravitreous injection of TA was performed on 17 patients (17 eyes) with CRVO between December 2003 and July 2004.ResultsDuring the follow-up of 4-10 months, the visual acuity improved in 16 patients, including alleviated or even disappeared cystoid macular edema (CME) in 5, and recurred macular edema in 5 with decreased visual acuity after 3 months. Six patients had increased ocular pressure after intra-ocular injection which alleviated after treated suitably. No neovascularization in angle or secondary neovascular glaucoma was found.ConclusionArgon laser photocoagulation combined with intravitreous injection of TA may improve the visual acuity and reduce complications in ischemic CRVO, though macular edema may recur in some cases. (Chin J Ocul Fundus Dis, 2005,21:224-225)
Objective To study and compare the clinical efficacy between intravitreal conbercept injection and (or) macular grid pattern photocoagulation in treating macular edema secondary to non-ischemic branch retinal vein occlusion (BRVO). Methods Ninety eyes of 90 patients diagnosed as macular edema secondary to non-ischemic BRVO were enrolled in this study. Forty-eight patients (48 eyes) were male and 42 patients (42 eyes) were female. The average age was (51.25±12.24) years and the course was 5–17 days. All patients were given best corrected visual acuity (BCVA), intraocular pressure, slit lamp with preset lens, fluorescence fundus angiography (FFA) and optic coherent tomography (OCT) examination. The patients were divided into conbercept and laser group (group Ⅰ), laser group (group Ⅱ) and conbercept group (group Ⅲ), with 30 eyes in each group. The BCVA and central macular thickness (CMT) in the three groups at baseline were statistically no difference (F=0.072, 0.286;P=0.930, 0.752). Patients in group Ⅰ received intravitreal injection of 0.05 ml of 10.00 mg/ml conbercept solution (conbercept 0.5 mg), and macular grid pattern photocoagulation 3 days later. Group Ⅱ patients were given macular grid pattern photocoagulation. Times of injection between group Ⅰ and Ⅲ, laser energy between group Ⅰ and Ⅱ, changes of BCVA and CMT among 3 groups at 1 week, 1 month, 3 months and 6 months after treatment were compared. Results Patients in group Ⅰ and Ⅲ had received conbercept injections (1.20±0.41) and (2.23±1.04) times respectively, and 6 eyes (group Ⅰ) and 22 eyes (group Ⅲ) received 2-4 times re-injections. The difference of injection times between two groups was significant (P<0.001). Patients in group Ⅱ had received photocoagulation (1.43±0.63) times, 9 eyes had received twice photocoagulation and 2 eyes had received 3 times of photocoagulation. The average laser energy was (96.05±2.34) μV in group Ⅰ and (117.41±6.85) μV in group Ⅱ, the difference was statistical significant (P=0.003). BCVA improved in all three groups at last follow-up. However, the final visual acuity in group Ⅰ and group Ⅲ were better than in group Ⅱ (t=4.607, –4.603;P<0.001) and there is no statistical significant difference between group Ⅲ and group Ⅰ (t=–0.802,P=0.429). The mean CMT reduced in all three groups after treating for 1 week and 1 month, comparing that before treatment (t=–11.855, –10.620, –10.254;P<0.001). There was no statistical difference of CMT between group Ⅰand Ⅲ at each follow up (t=0.404, 1.723, –1.819, –1.755;P=0.689, 0.096, 0.079, 0.900). CMT reduction in group Ⅰ was more than that in group Ⅱ at 1 week and 1 month after treatments (t=–4.621, –3.230;P<0.001, 0.003). The CMT in group Ⅲ at 3 month after treatment had increased slightly comparing that at 1 month, but the difference was not statistically significant (t=1.995,P=0.056). All patients had no treatment-related complications, such as endophthalmitis, rubeosis iridis and retinal detachment. Conclusions Intravitreal conbercept injection combined with macular grid pattern photocoagulation is better than macular grid pattern photocoagulation alone in treating macular edema secondary to non-ischemic BRVO. Combined therapy also reduced injection times comparing to treatment using conbercept injection without laser photocoagulation.
Objective To investigate the efficacy and the safety of external therapy of ultrasound (ETUS) enhancing thrombolysis on the experimental retinal vein occlusion. Methods The effect of ETUS enhanced thrombolysis and the impact of ultrasound energy and exposure were investigated respectively after both eyes of 51 rabbits with retinal branch vein occlusion created by photodynamic initiated thrombosis were divided into 4 groups. The first 2 groups are the ETUS groups, including one group (15 rabbits) underwent intravenous injection with urokinase (UK) (1700-2200 UK dissolved into 20 ml normal saline), and other group (12 rabbits) underwent intravenous injection with normal saline. In these 2 groups, each rabbit received ETUS treatment (1.0 W/cm2, 20 min) in one eye and the fellow eye did not which was as the control. The latter 2 groups are the energy and duration of ultrasound groups, and 12 rabbits in each group underwent ETUS with the energy of 0.7 and 1.0 W/cm2 respectively. Each of the 2 groups was divided into 3 subgroups (8 rabbits in each) according to the radiated durations (8, 14, and 20 minutes). All of the eyes except the control ones underwent ETUS with 1 MHz ultrasound and 100 Hz pulsed ultrasound once a day for 3 days. Fundus fluorescein angiography (FFA) was used to detect the vascular condition 4 days after ETUS, and at the 15th day, retinal light microscopy and electron microscopy were performed. Results The vascular recanalization rate in ETUS+UK treatment group was 66.7%, which is obviously higher than which in single UK group (20.0%, P=0.025), normal saline group (8.3%, P=0.005), and ETUS+ normal saline group (8.3%, P=0.005). The vascular recanalization rates in groups with different energy of ultrasound increased obviously as the radiated durations increased (P=0.006, 0.001), while no apparent effect of energy of ultrasound on the vascular recanalization rate was found in the groups with different radiated duration (Pgt;0.05). The eyes which had undergone ETUS treatment had retinal tissue damage and ultrastructure changes of the retinal ganglion cells (RGC), and deteriorated as the radiated duration increased. Conclusion ETUS may enhance the thrombolysis induced by urokinase in experimental retinal vein occlusion. Simultaneously, ETUS can lead to the damage of retinal tissue and changes of the ultrastructure of RGC. (Chin J Ocul Fundus Dis, 2007, 23: 166-169)