ObjectiveTo observe the macular choroidal and retinal pigment epithelium (RPE) thickness in tilted disc syndrome (TDS). MethodsThis is a descriptive study. Thirty eyes of 22 TDS patients (TDS group) and 30 eyes of 15 normal subjects (control group) were analyzed. Among TDS group, there were 8 males (11 eyes) and 14 females (19 eyes), the average age was (9.00±2.78) years old. The best corrected visual acuity (BCVA) was 0.3-1.0, and the average spherical equivalent degree was (-3.44±2.22) DS. Among the control group, there were 8 males (16 eyes) and 7 females (14 eyes), the average age was (9.33±1.11) years old. The best corrected visual acuity (BCVA)≥1.0, and the average spherical equivalent degree was (-3.18±1.13)DS. The difference of the spherical equivalent degree between two groups was not statistically significant (t=-1.648, P=0.110). Enhanced depth imaging techniques of frequency-domain optical coherence tomography was used to measure the thickness of choroid and RPE at totally 17 sites. There sites included subfoveal, 4 sites each (500, 1000, 1500 and 2000 μm from the fovea) at the horizontal (nasal/temple) and vertical (superior/inferior) directions. ResultsThe subfoveal choroidal thickness was (235.53±51.77) μm and (273.45±60.3) μm in TDS patients and control respectively, the difference was significant(t=-2.612,P=0.011). The difference of the choroidal thickness of the other 8 horizontal sites (F=24.180) and 8 vertical sites (F=23.390) in TDS group was statistically significant (P=0.000). The TDS choroidal thickness of all horizontal sites except nasal 1000 μm site was thinner than corresponding sites of the control group (P<0.05). The TDS choroidal thickness of the subfoveal site and 4 inferior vertical sites was thinner than corresponding sites of the control group (P<0.05). The subfoveal RPE thickness was (32.56±5.00) μm and (36.58±3.60) μm in TDS patients and control respectively, the difference was significant(t=-3.567,P=0.001). The subfoveal RPE thickness was the thickest among other 16 sites in both groups, and the TDS RPE thickness of all sites was thinner than control group, the difference was statistically significant (P<0.05). ConclusionThe choroidal and RPE thickness of TDS patient was thinner than normal subjects.
Objective To observe surgical outcomes and influencing factors of retinal detachment (RD) after phacoemulsification cataract extraction and intraocular lens (IOL) implantation. Methods The clinical data of 38 patients who underwent retinal detachment after phacoemulsification cataract extraction and intraocular lens implantation were retrospectively analyzed. All patients diagnosed via visual acuity, slit-lamp microscopy, direct or indirect ophthalmoscopy, A or Bscan ultrasonography and optical coherence tomography (OCT). There were 21 males (21 eyes) and 17 female (18 eyes). The age was from 42 to 83 years, with the mean of (57.4±11.2) years. There were nine patients (10 eyes) with simple macular hole RD (MHRD). Vitrectomy or scleral buckling or combined vitrectomy and scleral surgery were implemented according to RD range, the hole location and size, proliferative vitreoretinopathy (PVR) grading; simple MHRD eyes were treated posterior scleral reinforcement surgery. The followup was ranged from 3 to 12 months, with a mean of (11.9±6.8) months. Results The retina was reattached successfully through one operation in 36 eyes (92.3%), two eyes failed because of a relapse after surgery, and one eye finally succeeded by the third times of surgery. There were two eyes (5.1%) with improved vision, one eye (2.6%) with stable vision, and 36 eyes (92.3%) with decreased vision. Conclusion The ratio of the reattachment by one operation for RD after phacoemulsification cataract extraction and intraocular lens implantation is high, but the final visual prognosis remains poorly.
Objective To observe the incidence and related factors of macula hole retinal detachment(MHRD)after phacoemulsification cataract extraction and intraocular lens(IOL)implantation. Methods The clinical data of 10 076 patients(13 625 eyes) who underwent phacoemulsification cataract extraction and intraocular lens implantation were retrospectively analyzed. There are 1228 patients (1853 eyes) with high myopia. All the patients were examined by routine slitlamp microscopy, ophthalmoscopy as well as A- or B-scan ultrasonography. The phacoemulsification cataract extraction with transparent cornea incision or scleral tunnel incision, combined with intraocular lens implantation was performed in all the patients. The followup was ranged from 12 to 126 months, with a mean of (48.2plusmn;31.1)months. The MHRD was confirmed by the examinations of the fundus, B-scan ultrasonography and optical coherence tomography. The incidence of postoperative MHRD and the risk factors were analyzed. Results 10/13 625 eyes (0.073%) with MHRD were observed. 7/1853 high myopia eyes (0.378%) with MHRD were observed. The occurrence time of MHRD was ranged from 9 to 74 months after surgery, with a mean of 38.5 months. The cumulative risk was estimated at 0.16% (95% confidence interval, 0.05% -0.27%).Conclusions The incidence of MHRD after phacoemulsification cataract extraction combined with intraocular lens implantation is 0073%. The MHRD incidence of high myopia eyes is 0.378%. High myopia may be the risk factor for MHRD.
Objectives To evaluate the quality of ophthalmic clinical practice guidelines in China by using the AGREE Ⅱ instrument. Methods CBM, CNKI, VIP, and WanFang Data databases were electronically searched to collect Chinese guidelines for ophthalmology from inception to December 2017. Three reviewers independently evaluated the included guidelines using the AGREE Ⅱ instrument. Results A total of 60 Chinese clinical guidelines for ophthalmology were included. The average scores of the six domains including scope and purpose, stakeholder involvement, rigorism of development, clarity of presentation, applicability and editorial independence were 66.4%, 24.6%, 13.5%, 67.4%, 14.5%, and 19.3%, respectively. The guidelines published from 2013 to 2017 scored higher than those published previously in all areas except for domain 4 clarity of presentation. Conclusions The quality of current ophthalmic clinical practice guidelines in China is low, and there is still a big gap between them and the international guidelines. Guidelines developers should place more emphasis on developing regulations to improve stakeholder involvement, rigorism of development, applicability and editorial independence.
Objective To observe the etiological factors and variation of effects of nontraumatic severe vitreous hemorrhage. Methods A total of 1107 patients (1202 eyes) with nontraumatic severe vitreous hemorrhage who underwent vitrectomy from January 2005 to December 2011 were enrolled in this study. The patients were divided into A group (444 eyes of 415 patients were operated between January 2005 and December 2008) and group B (758 eyes of 692 patients between January 2009 and December 2011) according to admission date. The etiological factors and variations were recorded and retrospectively analyzed. Results Of all 444 eyes in group A, 156 eyes were due to retinal vein occlusion (RVO), 117 eyes associated with proliferative diabetic retinopathy (PDR), 61 eyes with retinal hole/retinal detachment (RH/RD), 42 eyes with Eales disease, 20 eyes with exudative agerelated macular degeneration (EAMD). These diagnoses accounting for 89.19% of the total eyes, were found to be the common causes in patients with severe vitreous hemorrhage, with RVO as the most common cause. Similarly in group B, severe vitreous hemorrhage was found in 347 eyes with proliferative diabetic retinopathy (PDR), 135 eyes with retinal hole/retinal detachment (RH/RD), 133 eyes with retinal vein occlusion (RVO), 25 eyes with Eales disease, 22 eyes with exudative age-related macular degeneration (EAMD), accounting for 87.87% of the total eyes. PDR was the most common cause instead of RVO to vitreous hemorrhage in this group. The number of vitreous hemorrhages increased year by year. Conclusions PDR, RH/RD, RVO, Eales disease and EAMD are the common causes of nontraumatic severe vitreous hemorrhage. There is a trend toward an increasing proportion of PDR among the causes of vitreous hemorrhage.