Objective To observe the efficacy and safety of intravitreal injection of ranibizumab (Lucentis) to treat idiopathic choroidal neovascularization(ICNV). Methods Fifty-four eyes from 54 patients with ICNV were included in this study. There were 24 males and 30 females. The patients aged from 21 to 49 years with a mean age of 32.57plusmn;7.06 years. The course of disease ranged from 6 days to 3 months with an average of 1.07plusmn;0.65 months. The examinations of best corrected visual acuity (BCVA) included Snellen chart and ETDRS visual acuity of ETDRS chart. Indirect ophthalmoscopy, fundus fluorescein angiography (FFA) and optic coherence tomography (OCT) were performed. The BCVA was hand motion 0.6. The average score of ETDRS chart was 32.00plusmn;16.41, and the average CRT (337.31plusmn;76.91) mu;m before treatment. All of the patients received an initial intravitreal injection of ranibizumab (0.5 mg,0.05 ml) and repeated treatments after the one-month follow-up if needed. The average follow-up period was 15.56plusmn;6.54 months. The changes of BCVA, ETDRS visual acuity, CRT and leakage of CNV before and after treatment were observed. Results One month after first injection, the mean number of ETDRS chart letters increased 16.81 to 48.81plusmn;16.96 with a significant difference (t=-11.991,P<0.01), in which 25 eyes increased more than 15 (46.30 %), while 2 eyes decreased more than 1 (3.70%). The mean CRT was (227.67plusmn;91.41) mu;m, which significantly decreased compared with before treatment (t=12.021,P<0.01). At the end of the follow-up period the number of repetitive intravitreal injections of ranibizumab was 1-4 times, with the mean of (1.59plusmn;0.71) times/eye. The mean number of ETDRS chart letters increased 17.20 to 49.20plusmn;16.60 with a significant difference (t=-11.390,P<0.01), in which 27 eyes increased more than 15 (50.00%), while 3 eyes decreased more than 1 (5.56%). The mean CRT was (227.69plusmn;89.30) mu;m, which significantly decreased compared with before treatment (t=10.872,P<0.01). There was complete CNV closure in 35 eyes (64.81%),partial closure in 11 eyes (20.37%),no change or expansion in 6 eyes (11.11%), and new CNV in 2 eyes (3.70%). No ocular or systemic adverse events were found after intravitreal injection of ranibizumab during the follow-up duration. Conclusions Intravitreal injection of ranibizumab is safe and effective for idiopathic choroidal neovascularization. It may improve the visual acuity and macular edema. However,long-term efficacy and safety remain to be further studied.
Objective T o observe the efficacy and safety of intravitreal injection of ranibizumab (Lucentis) for 12 consecutive months treating exudative age-related macular degeneration (EAMD). Methods This is an open and prospective study without control trial. Twenty-two eyes from 22 patients (18 males and 4 females) with EAMD diagnosed by fundus fluorescein angiography (FFA) and indocyanine green angiography (ICGA) were enrolled in this study. The patients aged from 46 to 79 years with the mean of 68.2plusmn;9.3 years. All of the patients received intravitreal injection of ranibizumab (0.5 mg, 0.05 ml) once a month for 12 consecutive months. The best-corrected visual acuity (BCVA) was obtained using the international standard visual acuity chart (converted into logMAR for statistical analysis). Central retinal thickness (CRT) was measured by optical coherence tomography (OCT) before and after each monthly treatment. Intraocular pressure (IOP) was measured using non-contact tonometry before treatment and 1 hour and 1 day after treatment. FFA and ICGA were performed every 3 months. The BCVA was 0.01 -0.9 with the average of 0.26plusmn;0.22. The average logMAR BCVA was 0.76plusmn;0.44, the CRT was 182-559 mu;m with the mean of (302.62plusmn;90.18) mu;m, and the IOP was normal before treatment. Only 13 of 22 patients completed 12 months of follow-up. The BCVA, CRT and IOP after treatment were compared with baseline using paired t test. Results Of all the 22 patients, the mean logMAR BCVA at 1 and 3 months after treatment were 0.52plusmn;0.32 and 0.37plusmn;0.27 respectively, both of which were significantly different compared with before treatment (t=4.518, 6.237;P<0.05). Of the 13 patients, the mean logMAR BCVA at 1, 3 and 12 months after treatment was 0.51plusmn;0.34, 0.35plusmn;0.26, 0.34plusmn;0.30 respectively. All of these measures were significantly different compared with 0.74plusmn;0.37 before treatment (t=3.443, 5.438, 4.756;P<0.05) . The mean CRT at 1, 3 and 12 months after treatment were (228.85plusmn;54.93), (231.00plusmn;38.94) and (262.92plusmn;70.48) mu;m. There were significant differences among before and 1, 3 months after treatment (t=2.914, 3.199;P<0.05), but not between before and 12 months after treatment (t=1.408, P>0.05). The first 3 injections contributed to the most BCVA gain with 6 patientsprime; BCVA increasing from 0.1- 0.5 to 0.5 or above. The greatest CRT reduction was obtained at 1 month after the first injection. IOP increased 1 hour after treatment and recovered within 1 day. No intravitreal injection-related side effects such as endophthalmitis were observed during the follow-up period. Conclusions Monthly intravitreal injections of ranibizumab may improve BCVA and macular edema. There was no adverse event during the follow-up duration.
Objective To observe the efficacy and safety of intravitreal injection of Ranibizumab(Lucentis) on exudative age-related macular degeneration (AMD). Methods To analyze retrospectively the clinical data of 56 patients with exudative AMD, which was diagnosed by examination of ETDRS charts, color fundus photograph, fluorescein angiography(FFA) or indocyanine green angiography(ICGA) and optical coherence tomography(OCT), were underwent intravitreal injection Lucentis 0.5 mg. Before the treatment, the ETDRS charts letter of 56 eyes was 25.1; choroidal neovascularization(CNA) was leaky which examined by FFA and ICGA; the average thickness of retina was 303.45 mu;m. Ranibizumab injection therapeutic times were 2.8, the average therapeutic times were 3.1. Follow-up time was 6-12 months (mean 8.7 months). Visual acuity (ETDRS charts letter), retinal thickness, leakage of CNV and operative complications before and after the treatment were analyzed. Results At the end of the follow-up period, the mean letter of ETDRS charts was 38.5, increased 13.4 letters (P<0.01), the ETDRS charts improved 15 or more letters in 22 eyes (39.3%), decreased more than 15 letters in 2 eyes (3.6%); the foveal thickness on OCT images were 303.45 mu;m before treatment and 191.35 mu;m a fter treatment, decreased significantly (P<0.00); FFA and/ or ICGA showed CNV complete closure in 12 eyes (21.4%), partial closure in 33 eyes (58.9%), no change in 9 eyes (16.1%) and new CNV in 1 eye (1.8%); Slight complications after operation disappeared during one week. Conclusion Intravitreal injection of Ranibizumab for exudative AMD was well tolerated, with an improvement in VA, FFA or ICGA , and OCT. (Chin J Ocul Fundus Dis,2008,24:160-163)
Objective To observe the characteristics of fundus autofluorescence (FAF) in patients with polypoidal choroidal vasculopathy (PCV) before and after intravitreal ranibizumab injections. Methods A retrospective case series. Seventeen patients (17 eyes) including 11 males and 6 females were enrolled in this study. Best corrected visual acuity (BCVA), FAF and indocyanine green angiography examination were performed on all eyes. The eyes were divided into hypo-autofluorescence group (8 eyes) and mixed autofluorescence group (9 eyes) according to the fluorescence degree. There was no differences of BCVA between two groups (t=2.403, P=0.072).All eyes received monthly intravitreal ranibizumab injections for 3 months followed by an as-needed reinjection schedule. All eyes were followed up for 12 months. FAF was performed at the 3rd, 6th and 12th month after first treatment. The changes of FAF characteristics and BCVA before and after treatment were observed. Results Before the treatment, the PCV lesions showed two distinct FAF patterns: the confluent hypo-autofluorescence at the polypoidal lesions and the granular hypo-autofluorescence at branching choroidal vascular networks (BVN). During the treatment, the abnormal FAF area of the whole lesions in all eyes reduced and gradually returned to normal. At the 3rd month after treatment, the central hypo-autofluorescence of polyps was surrounded by a hyper-autofluorescence ring, and with time, the ring was weakened or eliminated. However, all the hypo-autofluorescence findings in BVN at baseline were unchanged during the follow-up period. There was no significant differences in BCVA between hypo-autofluorescence group and hyper-autofluorescence group at different follow-up times (t=2.674, 2.862, 2.250; P=0.058, 0.052, 0.081). At final follow-up, 5 eyes (62.5%) in hypo-autofluorescence group and 3 eyes (33.3%) in hyper-autofluorescence group had increased BCVA, the different was not significant (P=0.347). Conclusions Before the treatment, there were the central hypo-autofluorescence of polyps and circumferential hypo-autofluorescence ring or confluent hypo-autofluorescence. After the treatment, the autofluorescence of polyps increased and then gradually returned to normal.
Objective To systematically review the efficacy of intravitreal injection of anti-vascular endothelial growth factors (anti-VEGF) on macular edema (ME) secondary to retinal vein occlusion (RVO). Methods Databases including PubMed, EMbase, Web of Science, The Cochrane Library, CNKI, WanFang Data and VIP were electronically searched to identify randomized controlled trials on different anti-VEGF drugs in the treatment of RVO-ME from inception to September 17th 2021. Two reviewers independently screened literature, extracted data, and assessed the risk bias of the included studies. Meta-analysis was then performed using RevMan 5.3 software. Results A total of 11 RCTs were included. Data from these studies included 2 436 eyes, of which 1 682 involved central retinal vein occlusion and 754 involved branch retinal vein occlusion. The results of meta-analysis showed that at 6 months of follow-up, anti-VEGF drug treatment of RVO-ME improved corrected visual acuity (MD=14.97, 95%CI 10.09 to 19.86, P<0.000 01) and reduced central retinal thickness (MD= −218.21, 95%CI −295.56 to −140.86, P<0.000 01) compared with control groups. At 12 months, anti-VEGF treatment of RVO-ME showed better improvement in corrected visual acuity compared with control group (MD=5.70, 95%CI 3.90 to 7.50, P<0.000 01). No statistically differences were observed in the improvements corrected visual acuity with different anti-VEGF drugs. However, for central retinal vein occlusion, different anti-VEGF drugs improved the central retinal thickness including aflibercept vs. bevacizumab (MD=−46.79, 95%CI −83.12 to −10.46, P=0.01), and bevacizumab vs. ranibizumab (MD=76.03, 95%CI 30.76 to 121.30, P=0.001) had significant differences. Conclusions The current evidence shows that anti-VEGF drugs can improve vision and reduce macular edema in the treatment of RVO-ME. Bevacizumab may be an effective alternative to ranibizumab or aflibercept. Existing evidence cannot determine differences between the improvement of best-corrected vision and the reduction of central retinal thickness during the long-term treatment of RVO, which requires to be verified by further research.
ObjectiveTo review the outcome of intravitreous anti-vascular endothelial growth factor (VEGF) treatment in patients with X-linked retinoschisis (XLRS) complicated with vitreous hemorrhage (VH). MethodsA retrospective clinical study. From March 1, 2016 to April 1, 2022, 18 patients (19 eyes) diagnosed with XLRS complicated with vitreous hemorrhage in Beijing Tongren Hospital, Capital Medical University of Eye Center were included. All the patients were male, with a median age of 7.05±3.8 years. Best corrected visual acuity (BCVA) and wide-angle fundus photography were performed in all the patients. BCVA was carried out using international standard visual acuity chart, and converted into logarithm of minimum resolution angle (logMAR) in statistics analysis. According to whether the patients received intravitreal injection of ranibizumab (IVR), the patients were divided into injection group and observation group, with 11 eyes in 10 cases and 8 eyes in 8 cases, respectively. In the injection group, 0.025 ml of 10 mg/ml ranibizumab (including 0.25 mg of ranibizumab) was injected into the vitreous cavity of the affected eye. Follow-up time after treatment was 24.82±20.77 months. The VH absorption time, visual acuity changes and complications were observed in the injection group after treatment. Paired sample t test was used to compare BCVA before and after VH and IVR treatment. Independent sample t test was used to compare the VH absorption time between the injection group and the observation group. ResultsLogMAR BCVA before and after VH were 0.73±0.32 and 1.80±0.77, respectively. BCVA decreased significantly after VH (t=-3.620, P=0.006). LogMAR BCVA after VH and IVR were 1.87±0.55 and 0.62±0.29, respectively. BCVA was significantly improved after IVR treatment (t=6.684, P<0.001). BCVA records were available in 5 eyes before and after IVR, and the BCVA values after VH and IVR were 0.58±0.31 and 0.48±0.20, respectively, with no statistically significant difference (t=1.000, P=0.374). BCVA increased in 1 eye and remained unchanged in 4 eyes after treatment. BCVA records were available in 5 eyes before VH and after VH absorption in the 8 eyes of the observation group. LogMAR BCVA before VH and after VH absorption were 0.88±0.28 and 0.90±0.26, respectively, with no significant difference (t=-1.000, P=0.374). After VH absorption, BCVA remained unchanged in 4 eyes and decreased in 1 eye. The absorption time of VH in the injection group and the observation group were 1.80±1.06 and 7.25±5.04 months, respectively. The absorption time of VH was significantly shorter in the injection group than in the observation group, the difference was statistically significant (t=-3.005, P=0.018). Multivariate linear regression analysis showed that IVR treatment was significantly correlated with VH absorption time (B=-6.66, 95% confidence interval -10.93--2.39, t=-3.40, P=0.005). In the injection group, VH recurrence occurred in 1 eye after IVR treatment. Vitrectomy (PPV) was performed in one eye. In the 8 eyes of the observation group, VH recurrence occurred in 2 eyes, subsequent PPV in 1 eye. The rate of VH recurrence and PPV was lower in the injection group, however, the difference was not statistically significant(P=0.576, 1.000). In terms of complications, minor subconjunctival hemorrhage occurred in 2 eyes and minor corneal epithelial injury occurred in 1 eye in the injection group, and all recovered spontaneously within a short time. In the injection group, 9 eyes had wide-angle fundus photography before and after IVR treatment. There was no significant change in the range of peripheral retinoschisis after treatment. No obvious proliferative vitreoretinopathy, infectious endophthalmitis, retinal detachment, macular hole, complicated cataract, secondary glaucoma or other serious complications were found in all the treated eyes, and there were no systemic complications. ConclusionIntravitreous anti-VEGF treatment may accelerate the absorption of vitreous hemorrhage in patients with XLRS. No impact is found regarding to the peripheral retinoschisis.
ObjectiveTo investigate the efficacy of 532 nm wavelength laser using indirect ophthalmoscope combined with ranibizumab (IVR) in treating stage 2 and greater pediatric Coats disease. MethodsA retrospective, non-controlled clinical study. From February 2018 to August 2020, 21 eyes of 21 patients with Coats disease stage 2 and greater diagnosed by examination in the Eye Center of Beijing Tongren Hospital were included in the study. Among them, 20 patients were males; 1 patient was female. Mean age was 5.00±1.92 years old. Stage 2A, 2B, 3A, 3B, and 4 were 2, 8, 7, 2, and 2 eyes, respectively. All eyes underwent wide-field fundus color photography and fluorescein fundus angiography (FFA). Best corrected visual acuity (BCVA) was performed in 17 eyes. Abnormal dilated retinal blood vessels, interretinal and subretinal exudates were found in all eyes. Abnormally dilated capillaries and aneurysms in the retina was shown in FFA examination. All eyes underwent 532 nm laser photocoagulation using indirect ophthalmoscope combined with IVR. Patients with severe retinal detachment of stage 3B or greater were treated by external drainage of subretinal fluid (SRF). The subsequent treatment was the same as before. The follow-up time was 35.67±6.13 months. Relevant examinations were performed using the same equipment and methods before. The frequency of treatment, visual acuity changes, anatomic prognosis, and complications were observed. ResultsThe frequency of eye photocoagulation was 2.43±0.98. The number of IVR treatments was 2.00±0.89. Three eyes were treated with SRF drainage in the first time. At the last follow-up, visual acuity improved, no change, and decreased in 5, 11, and 1 eyes after BCVA examination, respectively. In 21 eyes, the retina was in situ in 17 eyes; 5 eyes with retinal cysts. During the follow-up, cataract and vitreous hyperplasia occurred in 1 eye, which was treated by vitrectomy, and mild vitreous hyperplasia occurred in 1 eye. ConclusionIndirect ophthalmoscope 532 nm wavelength laser combined with IVR is an effective treatment for pediatric Coats disease.
ObjectiveTo analyze the clinical characteristics and evaluate the effect and safety of anti-vascular endothelial growth factor (VEGF) therapy in retinopathy of prematurity (ROP) in Sichuan province. MethodsA retrospective study. From January 2013 to January 2022, 156 patients (306 eyes) with ROP who received intravitreal anti-VEGF therapy for the first time in the Department of Ophthalmology, West China Hospital of Sichuan University were selected. According to the type of anti-VEGF drugs, the children were divided into intravitreal injection of ranibizumab (IVR) group and intravitreal injection of conbercept (IVC) group; IVC group was divided into hospital group and referral group according to the different paths of patients. After treatment, the patients were followed up until the disease degenerated (vascular degeneration or complete retinal vascularization) or were hospitalized again for at least 6 months. If the disease recurred or progressed, the patients were re-admitted to the hospital and received anti-VEGF drug treatment, laser treatment or surgical treatment according to the severity of the disease. Clinical data of these children was collected, including general clinical characteristics: gender, gestational age at birth (GA), birth weight (BW), history of oxygen inhalation; pathological condition: ROP stage, zone, whether there were plus lesions; treatment: treatment time, postmenstrual gestational age at the time of the first anti-VEGF drug treatment; prognosis: re-treat or not, time of re-treatment, mode of re-treatment; adverse events: corneal edema, lens opacity, endophthalmitis, retinal injury, and treatment-related systemic adverse reactions. The measurement data between groups were compared by t test, and the count data were compared by χ2 test or rank sum test. ResultsOf the 306 eyes of 156 children with ROP, 74 were male (47.44%, 74/156) and 82 were female (52.56%, 82/156). Each included child had a history of oxygen inhalation at birth. The GA was (28.43±2.19) (23.86-36.57) weeks, BW was (1 129±335) (510-2 600) g, and the postmenstrual gestational age was (39.80±3.04) (31.71-49.71) weeks at the time of the first anti-VEGF drug treatment. All patients were diagnosed as type 1 ROP, including 26 eyes (8.50%, 26/306) of aggressive ROP (A-ROP), 39 eyes (12.74%, 39/306) of zone Ⅰ lesions, and 241 eyes (78.76%, 241/306) of zone Ⅱ lesions. The children were treated with intravitreal injection of anti-VEGF drugs within 72 hours after diagnosis. Among them, 134 eyes (43.79%, 134/306) of 68 patients were treated with IVR, and 172 eyes (56.21%, 172/306) of 88 patients were treated with IVC. In IVC group, 67 eyes of 34 patients (38.95%, 67/172) were in the hospital group and 105 eyes of 54 patients (61.05%, 105/172) were in the referral group. 279 eyes (91.18%, 279/306) were improved after one treatment, 15 eyes (4.90%, 15/306) were improved after two treatments, and 12 eyes (3.92%, 12/306) were improved after three treatments. The one-time cure rate of IVR group was lower than that of IVC group, but the difference was not statistically significant (χ2=1.665, P=0.197). In different ROP categories, IVC showed better therapeutic effect in A-ROP, and its one-time cure rate was higher than that in IVR group, with statistically significant difference (χ2=7.797, P<0.05). In the hospital group of IVC group, the GA, BW and the postmenstrual gestational age at first time of anti-VEGF drug treatment were lower than those in the referral group, and the difference was statistically significant (t=-2.485, -2.940, -3.796; P<0.05). The one-time cure rate of the hospital group and the referral group were 94.94%, 92.38%, respectively. The one-time cure rate of the hospital group was slightly higher than that of the referral group, but the difference was not statistically significant (χ2=0.171, P=0.679). In this study, there were no ocular and systemic adverse reactions related to drug or intravitreal injection in children after treatment. ConclusionsCompared with the characteristics of ROP in developed countries, the GA, BW and postmenstrual gestational age of the children in Sichuan province are higher. Both IVR and IVC can treat ROP safely and effectively. There is no significant difference between the two drugs in the overall one-time cure effect of ROP, but IVC performed better in the treatment of A-ROP in this study.
ObjectiveTo observe the clinical characteristics and therapeutic effect of reactivation of retinopathy of prematurity (ROP) patients after intravitreal injection of ranibizumab (IVR). MethodsA retrospective case series study. Eleven children with ROP (21 eyes) who were reactivated after IVR in Shenzhen Eye Hospital from January 2019 to October 2021 were included in the study. Among them, there were 6 males (11 eyes) and 5 females (10 eyes), with the gestational age of (27.6±2.2) weeks and birth weight of (1 034.6±306.5) g. At the first IVR treatment, 14 eyes (63.7%, 14/22) had acute ROP (AROP), 8 eyes (36.3%, 8/22) had threshold lesions. Post-reactivation treatments include IVR, retinal laser photocoagulation (LP), or minimally invasive vitrectomy (MIVS). The follow-up time after treatment was 12 to 18 months. Birth gestational age, birth weight, treatment method, corrected gestational age at treatment, lesion stage before and after treatment, lesion reactivation and regression time were recorded. The clinical characteristics and efficacy were observed and analyzed. ResultsThe time from initial IVR treatment to reactivation was (8.2±3.5) weeks. The corrected gestational age of the child was (43.62±4.08) weeks. In 21 eyes, AROP, threshold lesion, pre-threshold lesion, and stage 4 lesion were in 2, 4, 12, and 3 eyes, respectively. The patients were treated with IVR, LP, IVR+LP, IVR+MIVS in 2, 13, 4 and 2 eyes, respectively. After the first reactivation treatment, the time of regression and stability was (8.4±4.9) weeks after treatment. There were 5 eyes with secondary reactivation of the lesion, and the lesion stages were stage 3, stage 4a and stage 5 in 2, 1 and 2 eyes, respectively. The mean reactivation time was (19.3±6.0) weeks after the last treatment. The patients in stage 3, stage 4a and stage 5 were treated with LP, LP+MIVS and IVR, respecitively, and the lesions subsided steadily during follow-up. At the last follow-up, 19 out of 21 eyes showed complete regression of the lesions, stable photocoagulation, regression of crista-like lesions, no additional lesions, and retinal leveling. All retinal detachment was "funnel-shaped" in 2 eyes. ConclusionsThe lesion reactivation of AROP after IVR treatment is more common. The early reactivation rate is higher after treatment. There is a possibility of reactivation twice after re-treatment.