Shin-Ya Nakao1, Masahiro Miyake2, Yoshikatsu Hosoda3, Eri Nakano4, Yuki Mori4, Ayako Takahashi4, Sotaro Ooto4, Hiroshi Tamura4, Yasuharu Tabara5, Kenji Yamashiro6, Fumihiko Matsuda5, Akitaka Tsujikawa4. 1. Department of Ophthalmology and Visual Sciences, Kyoto University Graduate School of Medicine, Kyoto, Japan; Department of Ophthalmology, Tenri General Hospital, Nara, Japan. 2. Department of Ophthalmology and Visual Sciences, Kyoto University Graduate School of Medicine, Kyoto, Japan; Center for Genomic Medicine, Kyoto University Graduate School of Medicine, Kyoto, Japan. Electronic address: miyakem@kuhp.kyoto-u.ac.jp. 3. Department of Ophthalmology, Osaka Red Cross Hospital, Osaka, Japan. 4. Department of Ophthalmology and Visual Sciences, Kyoto University Graduate School of Medicine, Kyoto, Japan. 5. Center for Genomic Medicine, Kyoto University Graduate School of Medicine, Kyoto, Japan. 6. Department of Ophthalmology, Otsu Red Cross Hospital, Shiga, Japan.
Abstract
PURPOSE: To describe the distribution of ocular biometry and refraction in Japanese adults. DESIGN: Cross-sectional analysis of a prospective cohort study. PARTICIPANTS: A total of 9850 individuals participated in the first follow-up of the Nagahama Prospective Cohort for Comprehensive Human Bioscience (the Nagahama Study) conducted between 2013 and 2016. Participants were between 34 and 80 years of age. METHODS: All participants underwent axial length (AL; in millimeters), anterior chamber depth (ACD; in millimeters), corneal diameter (white to white; in millimeters), and central corneal thickness (CCT; in micrometers) measurement (IOL Master; Carl Zeiss Meditec, Dublin, CA) and refraction (spherical equivalent [SE]; in diopters [D]) and corneal curvature (CC; in millimeters) measurement (ARK-530A; Nidek, Aichi, Japan). Distribution of these ocular biometric parameters and prevalence of myopia, high myopia, and extreme myopia were summarized. MAIN OUTCOME MEASURES: Distribution of ocular biometry and refraction. RESULTS: After standardization to the national population of 2015, estimates of mean AL and SE were 24.21 mm and -1.44 D, respectively. Estimates of mean CC, corneal diameter, CCT, and ACD were 7.69 mm, 12.01 mm, 543.96 μm, and 3.21 mm, respectively. After standardization of age and gender, the prevalence of myopia (SE, ≤-0.5 D) and high myopia (SE, ≤-6.0 D) were 49.97% and 7.89%, respectively. Approximately 70% of the younger participants (34-59 years of age) showed myopia, whereas high myopia was observed in approximately 10%. Although the number of individuals with myopia or high myopia was higher in the younger age groups, the prevalence of more extreme phenotypes remained stable across all ages, especially in women. Axial length of more than 30 mm was observed only in older women (n = 5 [0.05%]). CONCLUSIONS: We showed detailed distributions of various ocular biometry and refraction parameters using a large general Japanese cohort. Prevalences of myopia and high myopia from 2013 through 2016 were higher than those in earlier studies, which reflects recent environmental change. However, constant prevalence of extreme myopia across all ages suggests high genetic predisposition of the extreme phenotype.
PURPOSE: To describe the distribution of ocular biometry and refraction in Japanese adults. DESIGN: Cross-sectional analysis of a prospective cohort study. PARTICIPANTS: A total of 9850 individuals participated in the first follow-up of the Nagahama Prospective Cohort for Comprehensive Human Bioscience (the Nagahama Study) conducted between 2013 and 2016. Participants were between 34 and 80 years of age. METHODS: All participants underwent axial length (AL; in millimeters), anterior chamber depth (ACD; in millimeters), corneal diameter (white to white; in millimeters), and central corneal thickness (CCT; in micrometers) measurement (IOL Master; Carl Zeiss Meditec, Dublin, CA) and refraction (spherical equivalent [SE]; in diopters [D]) and corneal curvature (CC; in millimeters) measurement (ARK-530A; Nidek, Aichi, Japan). Distribution of these ocular biometric parameters and prevalence of myopia, high myopia, and extreme myopia were summarized. MAIN OUTCOME MEASURES: Distribution of ocular biometry and refraction. RESULTS: After standardization to the national population of 2015, estimates of mean AL and SE were 24.21 mm and -1.44 D, respectively. Estimates of mean CC, corneal diameter, CCT, and ACD were 7.69 mm, 12.01 mm, 543.96 μm, and 3.21 mm, respectively. After standardization of age and gender, the prevalence of myopia (SE, ≤-0.5 D) and high myopia (SE, ≤-6.0 D) were 49.97% and 7.89%, respectively. Approximately 70% of the younger participants (34-59 years of age) showed myopia, whereas high myopia was observed in approximately 10%. Although the number of individuals with myopia or high myopia was higher in the younger age groups, the prevalence of more extreme phenotypes remained stable across all ages, especially in women. Axial length of more than 30 mm was observed only in older women (n = 5 [0.05%]). CONCLUSIONS: We showed detailed distributions of various ocular biometry and refraction parameters using a large general Japanese cohort. Prevalences of myopia and high myopia from 2013 through 2016 were higher than those in earlier studies, which reflects recent environmental change. However, constant prevalence of extreme myopia across all ages suggests high genetic predisposition of the extreme phenotype.
Authors: Meng-Jun Zhu; Li Ding; Lin-Lin Du; Jun Chen; Xian-Gui He; Shan-Shan Li; Hai-Dong Zou Journal: Int J Ophthalmol Date: 2022-08-18 Impact factor: 1.645
Authors: Denis Plotnikov; Jiangtian Cui; Rosie Clark; Juho Wedenoja; Olavi Pärssinen; J Willem L Tideman; Jost B Jonas; Yaxing Wang; Igor Rudan; Terri L Young; David A Mackey; Louise Terry; Cathy Williams; Jeremy A Guggenheim Journal: Invest Ophthalmol Vis Sci Date: 2021-10-04 Impact factor: 4.799