Objective To observe the changes of intraocular pressure (IOP) after intravitreous injection wih triamcinolone acetonide (TA) and their affected factors. Methods The clinical data of 125 patients (125eyes) who had undergone intravitreous injection with TA were retrospectively analyzed. The patients (52 males and 73 females) aged from 17 to 83 years with the average age of 56.5. There were 49 patient (39.2%) with diabetic retinopathy (DR), 56 (44.8%) with retinal vein occlusion (RVO), and 20 (16.0%) with exudative age-related macular degeneration (AMD). One day before the treatment, IOP was measured by Goldmann applanation tonometry, and the basic IOP was 7~31 mm Hg (1 mm Hg=0.133 kPa) and the average IOP was (14.69plusmn;3.72) mm Hg. The patients were divided into two groups according to the basic IOP:below 15 mm Hg group (n=64) and 15 mm Hg or above group (n=61). All of the patients underwent intravitreous injection with 4mg TA. IOP was measured 1 day, 3 days, 1 week, 2 weeks, and 1 month after the treatment in the same way, respectively, and later was measured once every 1 month. The follow-up period was 3~21 months with the mean of 5 months. The elevation of IOP would be defined as the pressure of 21mmHg or higher. The changes of IOP in patients before and after the treatment, and with different diseases and ages were analyzed. Results Thirty-six patients (28.8%) had elevation of IOP after the treatment, out of whom 97.2% had the elevation within 3 months after the injection and decreased to the basic level 7 months after the injection. In these patients, there were 11 (17.19%) in the below 15 mm Hg group and 25 (40.98%) in 15 mm Hg or above group, and the difference between the two groups was statistically significant (P<0.01). During the followup period, the mean maximum IOP was (20.09plusmn;7.58) mmHg, which was 5.43 mmHg higher than that before the treatment(P<0.001). The mean maximum IOP of 53 patients (42.4%) after the treatment was 5 mm Hg higher than that before the treatment. The mean maximum IOP during the followup period was (18.19plusmn;4.73)mmHg in DR group,(22.50plusmn;9.30)mmHg in RVO group, and(18.12plusmn;6.09)mmHg in AMD group. The occurrence of the elevation of IOP in RVO group was obviously higher than that in the other 2 groups (P<0.01). The result of regression analysis showed that age was correlative with the elevation of IOP after the treatment: more risks of occurrence of high IOP were found in younger patients (P=0.000). Conclusion Elevation of IOP after intravitreous injection with TA is common, which is correlative with the basic IOP, age, and pathogeny. After the intravitreous injection with TA, the elevation of IOP often occurs in patients with high basic IOP before treatment, younger age, and RVO. (Chin J Ocul Fundus Dis, 2007, 23: 115-117)
Corticosteroids, anti-vascular endothelial growth factor, antibiotics and antiviral were the main 4 classes of drugs for intravitreal injection. Depending on the class and volume of medication, age and gender of patients, ocular axial lengths or vitreous humour reflux, intraocular pressure (IOP) can be elevated transiently or persistently after intravitreal injection. Transient IOP elevation occurred in 2 weeks after intravitreal injection, and can be reduced to normal level for most patients. Only a small portion of such patients have very high IOP and need intervention measures such as anterior chamber puncture or lowering intraocular pressure by drugs. Long term IOP elevation is refers to persistent IOP increase after 2 weeks after intravitreal injection, and cause optic nerve irreversible damage and decline in the visual function of patients. Thus drug or surgical intervention need to be considered for those patients with high and long period of elevated IOP. Large-scale multicenter clinical trials need to be performed to evaluate the roles of the drug and patients factors for IOP of post-intravitreal injection, and to determine if it is necessary and how to use methods reducing IOP before intravitreal injection.
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 short-term intraocular pressure changes of the affected eye after the implantation of dexamethasone vitreous implant (Ozurdex), and indirectly understand the tightness of the scleral perforation of the 22G implant device.MethodsThis is a prospective cohort design clinical observational study. From January 2018 to January 2020, 90 eyes (90 patients) who underwent vitreous Ozurdex implantation in the Department of Ophthalmology of Beijing Hospital were included in the study. There were 52 males (52 eyes), and 38 females (38 eyes); they were 14-79 years old. Forty-three eyes (43 patients) had retinal vein occlusion with macular edema, 29 eyes (29 patients) had uveitis with or without macular edema, 18 eyes (18 patients) had diabetic macular edema. All eyes underwent standard scleral tunnel vitreous cavity implantation Ozurdex treatment. The intraocular pressure was measured with a non-contact pneumatic tonometer 10 min before implantation (baseline) and 10, 30 min and 2, 24 h after implantation. The difference were compared between the intraocular pressure at different time points after implantation and the baseline. Wilcoxon signed rank test was used to compare intraocular pressure between baseline and different time points after implantation.ResultsThe average baseline intraocular pressure of the affected eye was 14.85 [interquartile range (IQR): 11.60, 17.63] mmHg (1 mmHg=0.133 kPa). The average intraocular pressure at 10, 30 and 2, 24 hours after implantation were 11.90 (IQR: 8.95, 16.30), 13.75 (IQR: 9.95, 16.80), 13.60 (IQR: 10.95, 17.20), and 14.65 (IQR: 12.20, 17.50) mmHg. Compared with the baseline intraocular pressure, the intraocular pressure decreased at 10 and 30 minutes after implantation, the difference was statistically significant (P<0.001, P=0.002); the intraocular pressure difference was not statistically significant at 2, 24 h after implantation (P=0.140, 0.280).ConclusionsThere is a statistically significant difference in intraocular pressure reduction compared with the baseline in 10 and 30 minutes after vitreous implantation of Ozurdex, and there is no statistically significant difference between 2, 24 hours. This suggests that the 22G scleral puncture port of the preinstalled implant device cannot be completely closed immediately, and short-term intraocular pressure monitoring after implantation should be appropriately strengthened.