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Objective:To evaluate the distribution characteristics of choroidal vascularity index (CVI) in macula among normal children using swept-source optical coherence tomography (SS-OCT), and to investigate the influencing factors.Methods:A cross-sectional study was conducted.Sixty-three children aged 6 to 12 years were enrolled in The First Affiliated Hospital of Zhengzhou University from May 2021 to November 2021.Spherical equivalent refraction, axial length (AL) and other ocular biological parameters were measured.Macula-centered CVI and choroidal thickness (ChT) were measured by SS-OCT angiography.According to the ETDRS partition, the obtained image was divided into macular central fovea (0-1 mm diameter), inner ring (1-3 mm diameter) and outer ring (3-6 mm diameter) zones.Data from the right eye were selected for statistical analysis.CVI in the three rings and four zones (superior, temporal, inferior and nasal zones) of the inner and outer rings were compared.Univariate and multiple linear regression analyses were used to analyze the correlation between CVI and sex, AL, anterior chamber depth (ACD), ChT and pupil diameter.This study adhered to the Declaration of Helsinki.The study protocol was approved by the Ethics Committee of The First Affiliated Hospital of Zhengzhou University (No.2021-KY-0399-003). Written informed consent was obtained from each guardian.Results:The average CVI in the macular central fovea, inner ring and outer ring were 0.35±0.12, 0.32±0.10 and 0.27±0.08, respectively, with a significant difference ( F=10.96, P<0.001), and significant differences in CVI were found in pairwise comparisons of the three ring zones (all at P<0.05). Significant differences in CVI were found among superior, temporal, inferior and nasal zones in inner and outer rings ( Fring=11.60, P=0.001; Fzone=12.02, P<0.05). The CVI was smaller in superior and nasal zones in inner ring than in temporal zone, greater in superior, temporal and inferior zones in outer ring than in nasal zone, smaller in superior zone of outer ring than that of the inner ring, and the differences were statistically significant (all at P<0.001). The single factor linear regression analysis showed that ChT in the fovea, inner ring and outer ring were the influencing factors of CVI in the three ring zones (all at β=0.001, P<0.001). Pupil diameter ( β=0.034, P=0.038; β=0.040, P=0.003; β=0.024, P=0.011) and ACD ( β=0.097, P=0.034; β=0.097, P=0.013; β=0.061, P=0.032) were the influencing factors of CVI in fovea, inner ring and outer ring.After multiple linear regression analysis, the regression equations were established as follows: CVI in the macular fovea=0.001×ChT in the macular fovea + 0.001×ChT in the inner ring+ 0.001×ChT in the outer ring-0.301 ( R2=0.514, F=6.875, P<0.001); CVI in the inner ring=0.001×ChT in the macular fovea+ 0.001×ChT in the inner ring+ 0.001×ChT in the outer ring+ 0.088×AL-0.307 ( R2=0.603, F=9.870, P<0.001); CVI in the outer ring=0.001×ChT in the macular fovea+ 0.001×ChT in the inner ring+ 0.001×ChT in the outer ring-0.135 ( R2=0.601, F=9.781, P<0.001). Conclusions:In children aged 6-12 years old, the CVI is higher in the macular central fovea than in inner and outer rings, and the CVI in nasal zone is the smallest in both inner and outer rings.The thicker the ChT, the higher the CVI in all zones in the macular area; the deeper the anterior chamber, the higher the CVI in the inner ring.
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Objective:To observe the effects of 0.01% atropine eye drops on ocular biometrics in myopic adolescents.Methods:A prospective cohort study was conducted.Two hundred and nineteen myopic adolescents who visited the First Affiliated Hospital of Zhengzhou University from June 2016 to June 2017 and completed the 1-year follow-up on time were enrolled.The 219 adolescents were divided into a 0.01% atropine+ single-vision spectacles (SV) group (119 cases) wearing single-vision spectacles with one drop of atropine eye drop applied to both eyes once nightly, and a simple SV group (100 cases) wearing SV only.Axial length (AL), corneal power and anterior chamber depth were measured with the IOLMaster.Lens power was calculated using the Bennett-Rabbetts formula.Intraocular pressure was measured by non-contact tonometry.Spherical equivalent (SE) was examined by cycloplegic autorefraction.Total astigmatism and corneal astigmatism were calculated by vector decomposition.The right eye data were analyzed to compare the ocular biometrics changes between the two groups, and multiple linear regression analysis was used to evaluate the influencing factors.This study adhered to the Declaration of Helsinki.The study protocol was approved by the Ethics Committee of First Affiliated Hospital of Zhengzhou University (No.2016-35). Written informed consent was obtained from guardians before any medical examination.Results:The SE change and AL elongation 12 months after treatment in 0.01% atropine+ SV group were (-0.47±0.45) D and (0.37±0.22) mm, respectively, which were significantly lower than (-0.70±0.60)D and (0.46±0.35)mm in simple SV group ( t=5.523, 9.651; both at P<0.001). There were significant differences in SE and AL between before and after treatment in both groups (SE: Fgroup=1.556, P=0.015; Ftime=12.538, P=0.002; AL: Fgroup=3.425, P=0.021; Ftime=18.235, P=0.008). The SE and AL at 4, 8 and 12 months after treatment were all increased in comparison with before treatment in both groups, showing statistically significant differences (all at P<0.001). The SE and AL at 8 and 12 months after treatment in 0.01% atropine+ SV group were smaller than in simple SV group, and the differences were statistically significant (all at P<0.001). At 8 and 12 months after treatment, total astigmatism and the anterior chamber depth were increased and the lens power was decreased in comparison with before treatment in both groups, and the differences were statistically significant (all at P<0.05). There was no significant difference in corneal astigmatism, corneal power and intraocular pressure at different time points before and after treatment between the two groups (all at P>0.05). In the multiple linear regression analysis, an equation of Δmyopic SE=-0.012-2.685×ΔAL-1.002×Δcorneal astigmatism-0.656×Δlens power+ 0.477×Δtotal astigmatism+ 0.363×Δanterior chamber depth-0.060×age+ 0.011×sex was used, showing the change of SE was mainly caused by the change of AL ( β=-2.685), then corneal power, lens power, total astigmatism and anterior chamber depth. Conclusions:In adolescents, 0.01% atropine eye drops can effectively retard myopia progression and axial elongation, showing no effect on astigmatism, corneal power, lens power, anterior chamber depth and intraocular pressure.The controlling effect of 0.01% atropine eye drops in the development of myopia is mainly achieved by reducing axial elongation.
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Objective:To observe the safety and efficacy of 0.01% atropine eye drops in the prevention of myopia onset in schoolchildren.Methods:A randomized double-blind controlled study was conducted.Sixty Chinese Han children (60 eyes) with binocular spherical equivalent (SE) between + 0.50 D and -0.75 D (pre-myopia) by cycloplegic autorefraction treated in The First Affiliated Hospital of Zhengzhou University were enrolled from July to October 2020.Aged 6-12 years old, the children were divided into 0.01% atropine group and control group according to a random number table, with 30 cases (30 eyes) in each group.The children were given one drop of 0.01% atropine or placebo eye drops in both eyes once a night.The SE, axial length (AL), accommodative amplitude and pupil diameter were compared before and after 3-month, 6-month of treatment between the two groups.Discomforts were recorded.This study adhered to the Declaration of Helsinki.The study protocol was approved by an Ethics Committee of The First Affiliated Hospital of Zhengzhou University (No.2020-KY-286). Written informed consent was obtained from guardian of each subject.Results:After treatment, 26 and 25 subjects completed the 6-month follow-up in 0.01% atropine group and control group, respectively, among which 3 subjects in 0.01% atropine group accounting for 11.5% and 9 in control group accounting for 36.0% developed myopia, showing a statistically significant difference ( χ2=4.238, P=0.040). There were significant differences in the overall comparison of SE and AL at different time points between before and after treatment ( Ftime=10.981, 81.854; both at P<0.001). At 3 and 6 months after treatment, there were significant increases in the SE and AL of control group and AL of 0.01% atropine group compared with respective baseline values (all at P<0.05). There was no significant difference in SE at 3 and 6 months after treatment compared with baseline SE in 0.01% atropine group (both at P>0.05). At 6 months after treatment, the change in SE in 0.01% atropine group was (-0.15±0.26)D, which was significantly less than (-0.34±0.35)D in control group, and the change in AL in 0.01% atropine group was (0.17±0.11)mm, Which was significantly shorter than (0.28±0.14)mm in control group, with significant differences between them ( t=2.207, P=0.032; t=3.127, P=0.003). There were significant differences in pupil diameter at different time points between before and after treatment ( Ftime=2.263, P=0.032). At 3 and 6 months after treatment, the pupil diameter was increased in comparison with baseline in 0.01% atropine group (both at P<0.05). There were significant differences in accommodative amplitude at different time points between before and after treatment in the two groups ( Fgroup=0.882, P=0.042; Ftime=0.337, P=0.033). The accommodative amplitude at 3 and 6 months after treatment were decreased in comparison with baseline in 0.01% atropine group and control group at corresponding time points (all at P<0.05). Within a month after treatment, photophobia in bright sunlight occurred in 5 cases in 0.01% atropine group, accounting for 16.7%(5/30), and 2 cases in control group, accounting for 6.7%(2/30), showing no significant difference ( χ2=0.647, P=0.421). No near-vision blur and other uncomfortable symptoms was found in the two groups. Conclusions:After 6-month application of 0.01% atropine eye drops, the prevalence of myopia in pre-myopia schoolchildren decreases and the changing rate of SE and AL slows down.The accommodative amplitude is slightly reduced and pupil diameter is slightly increased, with no obvious effects on study and life.