Objective To observe the therapeutic effect of autologous neurosensory retinal transplantation in repairing unhealed giant macular hole after pars plana vitrectomy (PPV). MethodsA prospective clinical study. From July 2022 to December 2023, 12 patients (12 eyes) with refractory large macular hole who received autologous neurosensory retinal transplantation treatment in Department of Ophthalmology of the First Affiliated Hospital of Zhengzhou University were selected for the study. The macular hole in affected eyes still did not close after PPV combined with inner limiting membrane removal or tamponade, and the diameter of macular hole were greater than 600 μm. All affected eyes received best corrected visual acuity (BCVA) and optical coherence tomography (OCT) examinations. The BCVA examination employed the international standard visual acuity chart, with results converted to logarithm of the minimum angle of resolution (logMAR) visual acuity for statistical analysis. During the surgery, a piece of healthy retinal neuroepithelial tissue, approximately 0.3 optic disc diameters larger than the macular hole, was removed from the upper retinal periphery and used as a graft. The graft was inserted into the macular hole with the aid of intraoperative OCT. Post-surgery, the vitreous cavity was filled with silicone oil or sterile air. The follow-up period after surgery was 6 months. The thickness of the retinal grafts was measured using the same equipment as before surgery at 3 days, 1, 3, and 6 months post-surgery. The primary focus was on observing the macular hole closure rate and changes in BCVA at 6 months post-operation. A paired t-test was used to compare BCVA before and after surgery. Results In the sample of 12 cases (12 eyes), there were 5 males with 5 eyes and 7 females with 7 eyes. The mean age was (50.4±12.6) years. The mean macular hole diameter was (1 085.6±344.0) μm; The mean eye axis length was (27.64±4.19) mm. At 6 months after surgery, all affected eyes showed macular hole were completely closed (100.0%, 12/12). The thickness of the retinal graft was measured as (206.8±21.0), (170.8±23.3), (165.6±31.6), and (157.9±31.1) μm at 3 days, 1, 3, and 6 months post-surgery, respectively. At before and 6 months after surgery, the logMAR BCVA of the affected eyes was 1.28±0.39 and 0.95±0.22, respectively. The difference in logMAR BCVA before and after surgery was statistically significant (t=3.40, P<0.05). Conclusion Autologous neurosensory retinal transplantation could effectively improve the closure rate of refractory large macular hole and improve or stabilize vision in the short run.
ObjectiveTo observe the histopathological changes in peripheral retinal lesions under intraoperative optical coherence tomography (iOCT). Methods A retrospective case series study. Eighty-eight patients (194 eyes) who underwent vitreoretinal surgery in the Department of Ophthalmology at the East Ward of the First Affiliated Hospital of Zhengzhou University from October 2021 to May 2022 in 94 eyes were included in the study. Among them, 49 cases were male and 39 cases were female, with the mean age of (50.93±17.55) years. Ninety-four eyes included 32 eyes with retinal detachment, 6 eyes with proliferative diabetic retinopathy, 28 eyes with vitreous hemorrhage, 8 eyes with ocular trauma, 14 eyes with the macular lesion, 1 eye with uveitis, 1 eye with family exudative vitreoretinopathy (FEVR), 1 eye with acute retinal necrosis (ARN), and 3 eyes with lens dislocation. All affected eyes were examined with iOCT during vitreoretinal surgery. The iOCT scanning of the peripheral retina was performed with the help of episcleral pressure. The pre-equatorial and serrated edge anterior and posterior of retinas were scanned according to the characteristics of different fundus diseases. Various abnormal fundus manifestations were recorded. Results In 94 eyes, 53 eyes (56.38%, 53/94) have different types of retinopathy in the peripheral retina. Of these, 7 eyes (7.45%) have retinal cystoid degeneration; 19 eyes (20.21%) have lattice degeneration; and 8 eyes (8.51%) have pigment degeneration; 9 eyes (9.57%) have pavement-like degeneration; 7 eyes (7.45%) have small occult holes; 1 eye (1.06%) has familial exudative vitreoretinopathy (FEVR) serrated edge "dyke-like" proliferative degeneration; 4 eyes (4.26%) have vitreous and retinopathy adhesions; and one eye (1.06%) has ARN. Conclusion With clear refractive media, iOCT can provide clear scans of different peripheral retinal lesions.
ObjectiveTo observe and analyze the changes of macular choroidal thickness in children with occult high myopia and its influencing factors.MethodsA prospective, non-randomized, contemporaneous controlled trial. From September 2019 to October 2020, 56 children (110 eyes) who first visited the ophthalmic clinic of the Affiliated Hospital of Chengde Medical College without any myopia correction training were enrolled in this study. There were 33 males (64 eyes) and 23 females (46 eyes), with the average age of 8.62±1.87 years old; the age ranged from 6 to 12 years old. According to the clinical manifestations of myopia in children, they were divided into occult high myopia group (27 cases, 52 eyes) and control group (29 cases, 58 eyes). In the 52 eyes of the occult high myopia group, the spherical equivalent refraction (SER) of -0.00 to -1.00 D, >-1.00 to -2.00 D, >-2.00 to -3.00 D were 15, 16 and 21 eyes. Among 58 eyes in the control group, the SER of -0.00 to -1.00 D, >-1.00 to -2.00 D, >-2.00 to -3.00 D were 21, 18 and 19 eyes, respectively. The macular fovea within 6 mm was divided into three concentric circles centered on the macular fovea, which included the central area with a diameter of 1 mm, the inner ring area with a diameter of 1-3 mm, and the outer ring area with a diameter of 3-6 mm, totally 9 areas. The inner ring and outer ring were divided into upper, lower, nasal and temporal areas. The changes of choroidal thickness in each macular area of children in occult high myopia group and control group were observed. The choroidal thickness in each macular area was compared between the two groups using independent sample t-test. Pearson correlation analysis was used to analyze the correlation between mean foveal choroidal thickness and gender, age, intraocular pressure, ocular axis, diopter and corneal curvature in occult high myopia group.ResultsChoroidal thickness in macular area of children in occult high myopia group was thinnest in nasal side and thickest in temporal side. Compared with the control group, the mean choroidal thickness in the 9 macular zones of children in the occult high myopia group was significantly thinner than that in the control group, and the difference was statistically significant (P<0.05). The mean choroidal thickness in each macular region decreased with the increase of diopter in children with occult high myopia. Compared with the control group with the same spherical equivalent, there was no significant difference in the area above the inner ring and the outer ring of the macular fovea in the occult high myopia group of -0.00 to -1.00 D and the temporal side of the inner ring and the outer ring of the macular fovea in the occult high myopia group of >-2.00 to -3.00 D (P>0.05), but there were significant differences among the other regions (P<0.05). Pearson correlation analysis results showed that the average choroidal thickness of the fovea in children with occult high myopia was negatively correlated with age (r=-3.410, R2=11.630, P=0.010), eye axis (r=1.420, R2=2.016, P=0.030) and diopter (r=-2.680, R2=7.182, P=0.040), but not significantly correlated with gender (r=0.166, R2=0.028, P=0.240), intraocular pressure (r=0.330, R2=0.109, P=0.800) and corneal curvature (r=-0.260, R2=0.068, P=0.850).ConclusionsThe thickness of macular choroidal in children with occult high myopia is the thinnest on the nasal side of the macular fovea and the thickest on the temporal side of the macular fovea. The mean choroidal thickness in each region of the macular is thinner than that in the common myopia children with the same diopter. The mean choroidal thickness of fovea is negatively correlated with age, ocular axis and diopter.
ObjectiveTo observe and analyze the changes of macular retinal thickness and related factors in children with occult myopia. MethodsA prospective longitudinal control study. From February 2021 to February 2022, 120 eyes of 60 children who first visited Department of Ophthalmology of The Affiliated Hospital of Chengde Medical College without any corresponding myopia correction treatment were included in the study. There were 32 males (64 eyes) and 28 females (56 eyes), with the age of 4-6 years. Visual acuity, medical optometry, corneal topography, spectral-domain optical coherence tomography (OCT) and axial length (AL) were measured at the first visit and 3, 6, 9 and 12 months. The children were divided into occult myopia group with 60 eyes of 30 cases and control group with 60 eyes of 30 cases according to visual acuity, equivalent spherical refraction (SE), AL and corneal curvature (CC). The macular fovea retinal thickness was measured by spectral-domain OCT enhanced deep imaging technique. According to the treatment and study of diabetic retinopathy, the retina within the 6 mm of the macular center was divided into three concentric circles with the macular fovea as the center, the central fovea of 1 mm, the inner ring of 1-3 mm and the outer ring of 3-6 mm. In the inner ring and outer ring, the retina was divided into 4 areas, upper and lower, left and right, with a total of 9 regions. The four regions of the inner ring and the outer ring were superior, inferior, nasal and temporal, respectively. The differences of AL, CC, SE, macular retinal thickness and the changes of related factors with time were compared between the occult myopia group and the control group. SE, AL, CC and retinal thickness in different macular regions of the two groups were compared by repeated measurement analysis of variance. In pairwise comparison, the minimum significant difference t test was used in different measurement time points, and the independent sample t test was used between groups at the same measurement time points. ResultsAt first diagnosis and after diagnosis, there were significant differences in SE (F=783.710), AL (F=742.192), macular fovea (F=330.292), inferior and temporal (F=158.250, 108.292) side of the outer ring retinal thickness in occult myopia group (P<0.01). In the control group, there were significant differences in the retinal thickness of SE (F=1 793.976), AL (F=457.362), macular fovea (F=31.029), inferior and temporal (F=7.405, 77.245) side of the outer ring retinal thickness (P<0.01). In both groups, with the prolongation of the time after the first diagnosis, the SE gradually increased, the AL gradually lengthened, and the thickness of the macular fovea, inferior and temporal side of the outer ring retinal thickness gradually thinned. Independent sample t test was performed on the data with differences between groups at the same time, and the results showed that at 3, 6, 9 and 12 months after first diagnosis, there were significant differences in SE, AL and CC between the occult myopia group and the control group (t=-4.801,-11.532, 16.276,-17.145), AL (t=24.203, 26.353, 27.057, 25.552); CC (t=-23.362,-25.382,-25.890,-24.350; P<0.01). There were significant differences in macular fovea, inferior and temporal side of the outer ring retinal thickness at 6, 9 and 12 months, macular fovea (t=-2.596,-2.542, -2.941; P<0.05), outer ring temporal (t =-2.285, -2.610, -2.506; P<0.05). ConclusionThe SE and AL of the occult myopia group and the control group increase with time, and the former increase more rapidly than the latter; the macular fovea, inferior and temporal side of the outer ring retinal become thinner, and the former become thinner than the latter.
ObjectiveTo observe the characteristics of choroidal thickness in patients with macular edema secondary to superior temporal branch retinal vein occlusion (BRVO-ME). MethodsA retrospective control study. From November 2020 to September 2021, 30 patients (30 eyes) with BRVO-ME (BRVO-ME group) were diagnosed by ophthalmology examination in Department of Ophthalmology, The Affiliated Hospital of Chengde Medical College and 14 healthy volunteers (28 eyes) were enrolled in the study. The choroidal thickness of macular area was measured by enhanced deep imaging technique of frequency domain optical coherence tomography. According to the subdivision of the diabetic retinopathy treatment group, the choroid within the 6 mm of the macular fovea was divided into three concentric circles with the macular fovea as the center, namely, the central area with the diameter of 1 mm, the inner ring of 1-3 mm and the outer ring of 3-6 mm. The inner ring area and the outer ring area are divided into upper, lower, nasal and temporal sides, respectively, which are denoted as S3, I3, N3, T3 and S6, I6, N6, T6, totaling 9 areas. To observe the distribution characteristics of choroidal thickness in different regions of two groups of eyes. The choroidal thickness of different macular regions was compared by independent sample t-test. ResultsThe choroidal thicknesses in the central area, S3, T3, I3, N3, S6, T6, I6, and N6 of the eyes in the control group and BRVO-ME group were 214.11±56.04, 207.89±57.92, 214.07±54.82, 207.14±61.54, 180.18±53.53, 204.25±59.60, 193.93±51.50, 190.54±51.21, 139.82±39.84 μm and 258.00±71.14, 256.43±68.70, 252.07±72.97, 244.37±68.49, 243.10±70.93, 247.20±68.36, 221.00±61.28, 223.77±58.64, 183.20±60.15 μm. In both groups, the choroidal thickness was the thickest in the central area, gradually thinning to the nasal side and temporal side, and the nasal choroidal thickness was thinner than other regions, and N6 area was the thinnest. Compared with the control group, the choroidal thickness of central area, S3, T3, I3, N3, S6, I6 and N6 in BRVO-ME group were significantly thicker (t=-2.899, -2.229, -2.172,-3.250, -2.543, -2.292, -3.214; P<0.05), there was no significant difference in T6 area (t=-1.814, P=0.075). ConclusionThe choroidal thickness of macular area in patients with BRVO-ME is thicker than that in normal subjects.