ObjectiveTo evaluate the factors that may influence the possibility of early hemorrhage after vitrectomy with silicon oil tamponade for proliferative diabetic retinopathy (PDR).MethodsSixty-seven eyes of 60 patients of PDR who received vitrectomy and silicon oil filled in Department of Ophthalmology, China-Japan Friendship Hospital during January 2014 and May 2017 were included in this study. There were 34 males and 26 females, with the mean age of 51.3±12.5 years. Groups were divided depending on the degree of postoperative hemorrhage in 3 days: non-hemorrhage group (NH group) and hemorrhage Group (H group) composed of two sub-group that were called slight hemorrhage (SH) and massive hemorrhage (MH) group. The treatment was conventional 25G or 27G pars plana vitrectomy combined with silicon oil tamponade. Forty eyes received phacoemulsification. The follow-up ranged from 8 to 16 months, with the mean follow-up of 11.2±5.6 months. The possible related factors of early hemorrhage after vitrectomy with silicon oil tamponade were analyzed. Independent t test, χ2 test and Fisher test were used in this study.Results55 eyes of 48 patients were in the NH group, while 12 eyes of 12 patients were in the H Group. There were statistical significances on the difference of age (t=?3.552, P=0.001), gender (P=0.052), hypertension (P=0.021), HbA1c (t=2.187, P=0.033) and presence of neovascularization of iris (χ2= 6.414, P=0.011), but there was no difference on diabetes duration (t=?0.451, P=0.654). Of the 12 patients in the H group, 7 were in the SH group and 5 were in the MH group. The MH group had a significantly higher HbA1c level (7.8±1.1)% compared with the SH Group (9.7±0.7)%, the difference was statistical significant (t=?3.256, P=0.009). Higher systolic blood pressure of MH group 186±7 mmHg (1 mmHg=0.133 kPa) acquired during operation was observed compared with SH Group 153±18 mmHg, the difference was statistical significant (t=?3.894, P=0.003). There was no statistical significances on the difference of age (t=1.954), gender, hypertension duration (t=?1.787), diabetes duration (t=?1.079), fasting blood-glucose (t=?0.361), diastolic blood pressure during operation (t=?0.811) between the two groups (P>0.05).ConclusionsYounger age, history of hypertension, presence of neovascularization of iris, higher level of HbA1c may predict greater possibility to cause early hemorrhage after vitrectomy with silicon oil tamponade for PDR. The patients with high level of HbA1c and high systolic pressure during the operation are more likely to undergo massive hemorrhage and secondary glaucoma.
The occurrence of high intraocular pressure (IOP) after vitrectomy for diabetic retinopathy (DR) is related to many factors, including the type and stage of DR, macular detachment, surgical methods, and the type of ocular tamponade. Early high IOP occurred mainly due to laser photocoagulation, inflammatory response, improper ocular tamponade, residual viscoelastic agents and ciliary body dysfunction. In addition to the above reasons, early-middle stage high IOP is also related to tamponade gas expansion peak, encircling scleral buckle and hyphema. The major reason for middle-stage high IOP is hyphema and silicon oil in anterior chamber. The reasons for late-stage high IOP are glaucoma, silicone oil emulsification, long-term use of glucocorticoid, and iris incision closure. Most high IOP can be controlled by proper treatment such as stopping use of glucocorticoid, anti-glaucoma eye drops and surgeries. But there are still a small number of patients with unexplained refractory high IOP, the mechanism need to be further explored.
ObjectiveTo investigate the risk factors for neovascular glaucoma (NVG) after vitrectomy in proliferative diabetic retinopathy (PDR) patients.
MethodsThree hundred and one patients (301 eyes) with PDR who underwent vitrectomy between January 2008 and December 2013 in our hospital were retrospectively evaluated. Risk factors for NVG after vitrectomy were identified by multivariate Logistic regression analysis.
ResultsTwelve of 301 patients (4.0%) developed postoperative NVG in 2 to 18 months after vitrectomy. The incidence of postoperative NVG peaked in 2 to 6 months after vitrectomy (7 eyes, 58.3%). Logistic regression analysis showed that postoperative retinal detachment was a significant risk factor for postoperative NVG in eyes with PDR (P < 0.001). Eyes with postoperative retinal detachment were more likely to develop NVG after vitrectomy than those without postoperative retinal detachment (OR=17.826). Gender, age, duration of diabetes, preoperative serum creatinine levels, glycated hemoglobin levels, preoperative intraocular pressure, preoperative lens status, combined phacoemulsification surgery and tamponade were not associated with postoperative NVG (P > 0.05).
ConclusionPostoperative retinal detachment is a major risk factor for NVG after vitrectomy in PDR.
Objective
To evaluate improvement of visual acuity for advanced proliferative diabetic retinopathy eyes with different complications after vitrectomy.
Methods
Four groups of advanced pr oliferative diabetic retinopathy (APDR) in 314 eyes with diabetes type Ⅱ and type Ⅰ were analyzed retrospectively: vitreous hemorrhage with limited traction retinal detachment (VH), extensive fibrovascular membranes with traction retinal detachment (TD), combined rhegmatogenous and traction retinal detachment (CRT) and cataract with vitreous hemorrhage or and traction retinal detachment (CHD).
Results
0.1 or better postoperative visual acuity was achieved in 59.5% of type Ⅱ and 66.7% of type Ⅰ in the VH group; 39.4% of type Ⅱ and 52.6% of type Ⅰ in the extensive TD group; 31.6% of the CRT grou p; 62.5% of the CHD group. The major intraoperative complication is iatrogenic retinal breaks. The causes of postoperative visual loss in present study included neovascular glaucoma (2.8% of type Ⅰ and 0.4% of type Ⅱ in aphakia, 25% of type Ⅱ in aphakia and 4.2% in pseudophakia), retinal detachment and CRAO.
Conclusion
The majority of APDR eyes obtained better visual improvement after vitrectomy and photocoagulation.
(Chin J Ocul Fundus Dis, 2001,17:171-174)
ObjectiveTo observe the effect of preoperative intravitreal ranibizumab injection (IVR) on the operation duration of vitrectomy and postoperative vision for the treatment of proliferative diabetic retinopathy (PDR).
MethodsA prospective study was carried out with the 90 PDR patients (90 eyes) who underwent vitrectomy. The 90 patients(90 eyes)were assigned to the vitrectomy only group(43 eyes) and the IVR combined with vitrectomy group (47 eyes). The IVR was performed 5-13 days prior to vitrectomy in the IVR combined with vitrectomy group. There were 15 eyes with fibrous proliferation PDR (FPDR), 16 eyes with advanced PDR (APDR) without involving the macular and 16 eyes with APDR involving the macular in the vitrectomy only group. There were 14 eyes with FPDR, 15 eyes with APDR without involving the macular and 14 eyes with APDR involving the macular patients in the IVR combined with vitrectomy group. All the eyes in the two groups were regularly operated by the same doctor to complete the vitrectomy. The start and end time of vitrectomy were recorded. The average follow-up time was 10 months. The changes of best corrected visual acuity (BCVA) before and 1, 3 and 6 months after surgery were compared between the two groups.
ResultsThe duration of operation of the FPDR type (t=-8.300) and the APDR involving the macular type (t=-2.418) in the IVR combined with vitrectomy group was shorter than vitrectomy only group (P < 0.05). The comparison of duration of operation of the APDR without involving the macular type in the two groups has no statistically significant difference (t=-1.685, P > 0.05). At 1 month after surgery, the comparison of BCVA of the IVR combined vitrectomy group and the vitrectomy only group in APDR involving the macular type has no statistically significant difference (t=0.126, P > 0.05). At 3, 6 months after surgery, the BCVA of the IVR combined vitrectomy group in APDR involving the macular type was significantly better than the BCVA of the vitrectomy only group (t=8.014, 7.808; P < 0.05). At 1, 3, and 6 months after surgery, the BCVA of the IVR combined vitrectomy group in FPDR type (t=3.809, 1.831, 0.600) and APDR without involving the macular type (t=0.003, 1.092, 3.931) compared with pre-treatment, the difference were not statistically significant (P > 0.05); the BCVA in APDR without involving the macular type compared with pre-treatment, the difference was distinctly statistically significant (t=2.940, 4.162, 6.446; P < 0.05); the BCVA in APDR involving the macular type (t=0.953, 1.682, 1.835) compared with pre-treatment, the difference were not statistically significant (P > 0.05).
ConclusionPreoperative IVR of PDR can shorten the operation duration and improve the BCVA of APDR involving the macular type.
Objective To investigate the risk factors associated with neovascular glaucoma (NVG) after pars plana vitrectomy (PPV) in eyes with proliferative diabetic retinopathy (PDR). Methods Retrospective study. One hundred and thirty-seven patients (137 eyes) with PDR who underwent PPV were recruited. There were 85 males and 52 females. The average age was (60.1±8.8) years old. The duration of diabetes was (10.2±3.6) years. There were 49 patients with ipsilateral carotid artery stenosis. Fifty-three eyes underwent intravitreal ranibizumab or conbercept injection before PPV. All eyes were treated with 23G standard three-port PPV. The average follow-up time after PPV was 11.5 months. Fundus fluorescein angiography (FFA) was conducted in postoperative 4-6 weeks to observe non-perfused retinal areas. Risk factors, such as ipsilateral carotid artery stenosis, the presence of non-perfusion in retina after PPV and the application of anti-vascular endothelial growth factor (VEGF) drugs before PPV, were identified by logistic regression. Results Twenty of 137 patients (14.6%) developed postoperative NVG after PPV. Ipsilateral carotid artery stenosis [odds ratio (OR) =5.048, 95% confidence interval (CI) 2.057-12.389,P=0.000] and the presence of non-perfusion in retina after PPV (OR=4.274, 95%CI 1.426-12.809,P=0.009) were significant risk factors for postoperative NVG, while the application of anti-VEGF drugs was not (OR=1.426, 95%CI 0.463-4.395,P=0.536). But the time from PPV to the onset of NVG varies significantly between the two groups of injection of anti-VEGF drugs or not (t=?4.370,P=0.000). Conclusions Risk factors associated with NVG after PPV in eyes with PDR included ipsilateral carotid artery stenosis and the presence of non-perfusion in retina after PPV. The application of anti-VEGF drugs before PPV can delay the onset of NVG in PDR eyes after vitrectomy.
Objective
To observe the short-term intraocular pressure after 25G+ pars plana vitrectomy (PPV) and analyze the possible influencing factors in rhegmatogenous retinal detachment (RRD) and proliferative diabetic retinopathy (PDR) eyes.
Methods
This is a retrospective case-control study. A total of 160 patients (163 eyes) of RRD and PDR who underwent 25G+ PPV were enrolled in this study. There were 88 males (89 eyes) and 72 females (74 eyes), with the mean age of (50.37±13.24) years. There were 90 patients (92 eyes) with RRD (the RRD group) and 70 patients (74 eyes) with PDR (the PDR group). Best corrected visual acuity (BCVA) and intraocular pressure (IOP) were performed on all the patients. The BCVA was ranged from hand motion to 0.6. The average IOP was (12.61±4.91) mmHg (1 mmHg=0.133 kPa). There were significant differences in crystalline state (χ2=9.285, P=0.009), IOP (χ2=58.45, P=0.000), history of PPV (χ2=4.915, P=0.027) and hypertension (χ2=24.018, P=0.000), but no significant difference in sex (χ2=0.314, P=0.635) and age (χ2=5.682, P=0.056) between the two groups. A non-contact tonometer has been used to measure IOP on postoperative day 1 and 3. The postoperative IOP distribution has been divided into five groups: severe ocular hypotension (≤5 mmHg), mild ocular hypotension (6 - 9 mmHg), normal (10 - 21 mmHg), mild ocular hypertension (22 - 29 mmHg), severe ocular hypertension (≥30 mmHg). Logistic regression analysis has been used to analyze the risk and protective factors.
Results
On the first day after surgery, there were 21 eyes (12.9%) in mild ocular hypotension, 96 eyes (58.9%) in normal, 22 eyes (13.4%) in mild ocular hypertension and 24 eyes (14.7%) in severe ocular hypertension. On the first day after surgery, there were 18 eyes (11.0%) in mild ocular hypotension, 117 eyes (71.7%) in normal, 23 eyes (14.1%) in mild ocular hypertension and 5 eyes (3.1%) in severe ocular hypertension. There was no significant difference of IOP distribution between the two groups (Z=?1.235, ?1.642; P=0.217, 0.101). The results of logistic regression analysis showed that silicone tamponade was a risk factor for ocular hypertension in PDR eyes on the first day after surgery [odds ratio (OR)=15.400, 95% confidence interval (CI) 3.670 - 64.590; P<0.001], while intraocular lens was the risk factor for ocular hypotension in PDR eyes on third day after surgery (OR=19.000, 95%CI 1.450 - 248.2; P=0.025). As for RRD eyes, the ocular hypotension before surgery was a risk factor for ocular hypertension on the third day after surgery (OR=3.755, 95%CI 1.088 - 12.955; P=0.036). For all eyes, silicone tamponade (OR=0.236, 95%CI 0.070 - 0.797), air tamponade (OR=0.214, 95%CI 0.050 - 0.911) and inert gas tamponade (OR=0.092, 95%CI 0.010 - 0.877) were protective factors for ocular hypotension on the first day after surgery (P=0.020, 0.037, 0.038); silicone tamponade was protective factor for ocular hypotension on the third day after surgery (OR=0.249, 95% CI 0.066 - 0.94, P=0.040); while aphakic eyes was the risk factor for ocular hypotension on third day after surgery (OR=7.765, 95% CI 1.377 - 43.794, P=0.020). The ocular hypotension before surgery was a risk factor for ocular hypertension on the third day after surgery (OR=4.034, 95% CI 1.475 - 11.033, P=0.007).
Conclusions
The abnormal IOP is common after 25G+ PPV with a rate from 28.3% to 31.1%. Silicone tamponade, air tamponade and inert gases tamponade are protective factors for postoperative ocular hypotension, aphakic eye is risk factor for postoperative ocular hypotension. Ocular hypotension before surgery and silicone oil tamponade are risk factors for postoperative ocular hypertension.
ObjectiveTo observe the effect of microincision vitrectomy assisted with intravitreaI injection of ranibizumab (IVR) in proliferative diabetic retinopathy (PDR) treatment.
MethodsThis is a prospective, randomized, and comparative case series study. A total of 92 patients (92 eyes) with PDR were recruited to have microincision vitrectomy with (combined group) or without (PPV group) IVR. There are 48 eyes in the combined group and 44 eyes in the PPV group. The average operation time, iatrogenic breaks, the use of tamponade and electric coagulation, postoperative bleeding and best corrected visual acuity were comparatively analyzed among the two groups.The mean follow-up was (14.3±5.2) months.
ResultsThe average operation time was (59.4±18.5) min in the combined group and (74.6±16.2) min in the PPV group. The rate of silicone oil tamponade (χ2=4.619), inert gas tamponade (χ2=4.290), electric coagulation (χ2=8.039) and iatrogenic breaks (χ2=4.330) in the combined group were significantly decreased compared with PPV group(P<0.05). The mean logMAR BCVA was 0.83±0.44 in the combined group and 1.37±0.53 in the PPV group, which significantly improved from preoperatively (t=3.257, 3.012; P<0.05). The rate of BCVA improvement in the combined group was significantly higher than that in the PPV group (t=2.972, P<0.05). The incidence of the recurrent vitreous hemorrhage was 2.1% in the combined group and 9.1% in the PPV group (χ2=6.741, P<0.05). There was no severe complication associated with surgery, such as choroidal detachment, retinal detachment and endophthal-mitis.
ConclusionIVR before the microincision vitrectomy can shorten the operation time, reduce the use of electric coagulation and intraocular tamponade, and improve visual acuity for PDR patients.
ObjectiveTo evaluate the full thickness idiopathic macular hole (IMH) closure rates in patients positioning non-supine (NSP) compared with patients positioning face-down (FDP).
MethodsA computerized search was conducted in the PubMed, Chinese Biomedical Database, China National Knowledge Infrastructure, and VIP database. All the included studies were divided into NSP and FDP group. A total of 9 papers were included in this meta analysis, including 285 eyes (145 eyes with small hole ≤400 μm, 104 eyes with large hole >400 μm) in NSP group and 303 eyes (141 eyes with small hole and 124 eyes with large hole ). RevMan 4.2 software was applied for investigating heterogeneity and meta-analysis, and the risk of publication bias was evaluated.
ResultsMeta analysis indicated that there was statistical significance on closure rates betwen NSP and FDP group. The difference of closure rates in small macular hole eyes between NSP and FDP group was statistically significant (OR=0.45, 95%CI 0.13-1.51;P=0.20). The difference of closure rates in large macular hole eyes between NSP and FDP group was statistically significant (OR=0.35, 95%CI 0.17-0.75;P=0.006).
ConclusionNSP is equally effective as strict FDP in the repair of small macular hole. Post-operative FDP may improve the macular hole closure rates for holes larger than 400 μm.
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.
