2019—2024年以行政辖区小学生人群为基础的近视情况调查

doi:10.19723/j.issn.1671-167X.2026.03.010

北京大学学报（医学版） ›› 2026, Vol. 58 ›› Issue (3): 513-519. doi: 10.19723/j.issn.1671-167X.2026.03.010

2019—2024年以行政辖区小学生人群为基础的近视情况调查

杨明佳¹^,², 吴姜雪³^,*(), 王静³, 刘扬¹^,², 李忠民³, 李静静³, 李宏田¹^,²^,⁴, 周玉博¹^,²^,⁴, 刘建蒙¹^,²^,⁴^,*()

1. 北京大学生育健康研究所/国家卫生健康委员会生育健康重点实验室，北京 100191
2. 北京大学公共卫生学院流行病与卫生统计学系，北京 100191
3. 阜阳市妇女儿童医院眼科，安徽阜阳 236001
4. 北京大学女性生育力促进全国重点实验室，北京 100191

收稿日期:2026-02-25 出版日期:2026-06-18 发布日期:2026-04-10
通讯作者: 吴姜雪, 刘建蒙
基金资助:
北大医学-阜阳妇儿临床转化研究联合实验室项目

A population-based survey of myopia on primary school students in an administrative district, 2019 to 2024

Mingjia YANG¹^,², Jiangxue WU³^,*(), Jing WANG³, Yang LIU¹^,², Zhongmin LI³, Jingjing LI³, Hongtian LI¹^,²^,⁴, Yubo ZHOU¹^,²^,⁴, Jianmeng LIU¹^,²^,⁴^,*()

1. Institute of Reproductive and Child Health, National Health Commission Key Laboratory of Reproductive Health, Peking University School of Public Health, Beijing 100191, China
2. Department of Epidemiology and Biostatistics, Peking University School of Public Health, Beijing 100191, China
3. Department of Ophthalmology, Fuyang Women and Children's Hospital, Fuyang 236001, Anhui, China
4. State Key Laboratory of Female Fertility Promotion, Peking University, Beijing 100191, China

Received:2026-02-25 Online:2026-06-18 Published:2026-04-10
Contact: Jiangxue WU, Jianmeng LIU
Supported by:
the Peking University Medicine & Fuyang Women and Children's Hospital Joint Laboratory Program on Clinical Translational Research

摘要/Abstract

摘要：

目的: 描述2019年小学生近视患病率和等效球镜度数情况，并对比分析其在2020年及2024年的变化情况，以获得相关基础数据并探究视屏时间变化对视力的潜在影响，为相关部门制定有针对性的近视防控措施提供参考数据。方法: 本研究为横断面研究，对象为2019年(基线时期)、2020年(视屏时间增加期)、2024年(视屏时间恢复期)视力筛查的全部小学生，年级、性别、视力与屈光检查数据均来自筛查数据库。应用FKR-710电脑验光仪在未散瞳状态下进行屈光检查，获得球镜度数和柱镜度数；应用K238-AZ液晶视力表检测裸眼远视力。等效球镜度数=球镜度数+1/2×柱镜度数；近视定义为任意一眼裸眼远视力＜5.0且该眼等效球镜度数≤-0.50 D。采用百分比、均数及95%置信区间(confidence interval, CI)描述近视患病率和等效球镜度数，采用卡方检验和单因素方差分析比较不同年份近视患病率和等效球镜度数差异，再按年级分层分析。结果: 共筛查小学生183 204名，2019年45 294名、2020年52 922名和2024年84 988名。2019年近视患病率为30.8%(95%CI: 30.4%, 31.2%)，男生28.4%(27.8%, 29.0%)、女生33.7%(33.1%, 34.3%)(P＜0.001)；一年级11.0%(10.4%, 11.6%)，二至六年级35.7%(35.2%, 36.2%)，呈随年级而升高的趋势(P＜0.001)。2020年近视患病率为35.1%，较2019年上升4.3 (3.7, 4.9)个百分点(P＜0.001)；2024年为41.8%，较2020年继续惯性上升6.7 (6.2, 7.2)个百分点(P＜0.001)。分年级看，与2019年相比，2020年一年级升幅最大；与2020年相比，2024年一年级惯性升幅最小。此外，对等效球镜度数的定量分析显示，2020年等效球镜度数(-0.72 D)较2019年下降0.21 D (0.19 D, 0.23 D)(P＜0.001)，2024年等效球镜度数(-0.68 D)较2020年回升0.04 D (0.02 D, 0.06 D)(P＜0.001)；按年级分层显示一年级学生2024年(0.08 D)已接近2019年水平(0.09 D)。结论: 研究地区小学生2019年近视患病率为30.8%，高于全球水平，接近美国的两倍、德国的四倍，提示小学生近视防控工作依旧面临挑战。2020年和2024年近视患病率高于2019年；低年龄组2020年升幅最大，2024年惯性升幅最小且定量的等效球镜度数已恢复至2019年水平，但高年龄组则不然，提示视屏时间增加等生活习惯变化影响小学生近期视力，低龄学生眼球结构具有可塑性，对负性暴露较敏感并且脱离暴露后又易于恢复，具体机制有待进一步研究。此外，小学生近视患病率女生高于男生且随年级而上升的特点与既往研究结果一致。

关键词: 视力筛查, 近视, 等效球镜度数, 学校, 学生

Abstract:

Objective: To describe the myopia prevalence and spherical equivalent among primary school students in a district of Anhui Province in 2019, to analyze their changes in 2020 and 2024, to obtain baseline data, and to explore the potential impact of changes in screen time on vision, providing scientific evidence for myopia prevention and control strategies. Methods: This cross-sectional study included all the primary school students who underwent vision screening in 2019 (baseline period), 2020 (period of increased screen time), and 2024 (period of slightly resumed screen time). Data on grade, gender, uncorrected distance visual acuity, and refraction were extracted from the screening database. Noncycloplegic refraction was assessed using an FKR-710 autorefractor to measure sphere and cylinder, and uncorrected distance visual acuity was assessed using an K238-AZ LCD visual acuity chart. The spherical equivalent was calculated as sphere + 0.5 × cylinder. Myopia was defined as uncorrected distance visual acuity < 5.0 in either eye with a corresponding spherical equivalent ≤ -0.50 D. Myopia prevalence and spherical equivalent were described using percentage and mean with 95%confidence interval (CI). The Chi-square test and One-way analysis of variance were used to compare myopia prevalence and spherical equivalent across different years, followed by stratified analysis by grade. Results: A total of 183 204 students were screened: 45 294 in 2019, 52 922 in 2020, and 84 988 in 2024. In 2019, the myopia prevalence was 30.8%(95%CI: 30.4%, 31.2%), higher in girls (33.7%) than in boys (28.4%) and increased with grade (P < 0.001), rising from 11.0%in Grade 1 to 35.7%in Grades 2-6. Compared with 2019, the myopia prevalence in 2020 increased by 4.3 (3.7, 4.9) percentage points to 35.1%(P < 0.001). By 2024, it further increased by 6.7 (6.2, 7.2) percentage points from the 2020 level to 41.8%(P < 0.001). In grade-stratified analyses, compared with 2019, Grade 1 students showed the largest increase in 2020; compared with 2020, Grade 1 students showed the smallest subsequent increase in 2024. Quantitative analysis of spherical equivalent showed that the mean spherical equivalent in 2020 was -0.72 D, representing a myopia shift of -0.21 D (-0.23 D, -0.19 D) compared with the 2019 level (P < 0.001); by 2024, the mean spherical equivalent was -0.68 D, indicating a hyperopic shift of 0.04 D (0.02 D, 0.06 D) compared with the 2020 level (P < 0.001). Further grade-stratified analyses indicated that the mean spherical equivalent for Grade 1 students in 2024 (0.08 D) had nearly returned to the 2019 level (0.09 D). Conclusion: The myopia prevalence among primary school students in the study area was 30.8%in 2019, higher than the global level and approximately twice that of the United States and four times that of Germany, indicating that myopia prevention and control among primary school students remains challenging. The myopia prevalence in 2020 and 2024 was higher than in 2019, suggesting that lifestyle changes, such as increased screen time, affect the short-term visual status. Younger students experienced the greatest increase in myopia prevalence in 2020 and the mildest subsequent increased in 2024, and their spherical equivalent in 2024 had almost recovered to the 2019 level, but not for older students. These findings indicate greater ocular plasticity in younger students, i.e. more sensitive to negative exposures and easier to recover after removing such exposures, warranting further investigation on the underlying mechanisms. Additionally, patterns of higher myopia prevalence in girls than in boys and a gradual increase with grade support previous studies, also enhancing the reliability of the relevant results in our study.

Key words: Vision screening, Myopia, Spherical equivalent, School, Students

中图分类号:

R778.11

杨明佳, 吴姜雪, 王静, 刘扬, 李忠民, 李静静, 李宏田, 周玉博, 刘建蒙. 2019—2024年以行政辖区小学生人群为基础的近视情况调查[J]. 北京大学学报（医学版）, 2026, 58(3): 513-519.

Mingjia YANG, Jiangxue WU, Jing WANG, Yang LIU, Zhongmin LI, Jingjing LI, Hongtian LI, Yubo ZHOU, Jianmeng LIU. A population-based survey of myopia on primary school students in an administrative district, 2019 to 2024[J]. Journal of Peking University (Health Sciences), 2026, 58(3): 513-519.

图/表 2

表1

2019—2024年不同年级、不同性别小学生近视患病率"

Items	2019			2020				2024
Items	n	n_myopia	Prevalence/%	n	n_myopia	Prevalence/%	Prevalence change^a/%	n	n_myopia	Prevalence/%	Prevalence change^b/%
Grade 1
Boy	5 081	556	10.9 (10.1, 11.8)	5 625	1 006	17.9 (16.9, 18.9)		7 027	1 442	20.5 (19.6, 21.5)
Girl	3 929	435	11.1 (10.1, 12.1)	4 694	897	19.1 (18.0, 20.2)		6 444	1 133	17.6 (16.7, 18.5)
Subtotal	9 010	991	11.0 (10.4, 11.6)	10 319	1 903	18.4 (17.7, 19.2)	7.4 (6.4, 8.4)	13 471	2 575	19.1 (18.5, 19.8)	0.7 (-0.3, 1.7)
Grade 2
Boy	4 743	733	15.5 (14.4, 16.5)	5 429	1 163	21.4 (20.3, 22.5)		7 810	2 049	26.2 (25.3, 27.2)
Girl	4 027	676	16.8 (15.6, 17.9)	4 394	1 007	22.9 (21.7, 24.2)		7 106	1 892	26.6 (25.6, 27.7)
Subtotal	8 770	1 409	16.1 (15.3, 16.8)	9 823	2 170	22.1 (21.3, 22.9)	6.0 (4.9, 7.2)	14 916	3 941	26.4 (25.7, 27.1)	4.3 (3.2, 5.4)
Grade 3
Boy	4 281	1 127	26.3 (25.0, 27.6)	5 238	1 526	29.1 (27.9, 30.4)		7 701	2 830	36.7 (35.7, 37.8)
Girl	3 668	1 087	29.6 (28.2, 31.1)	4 443	1 497	33.7 (32.3, 35.1)		6 953	2 783	40.0 (38.9, 41.2)
Subtotal	7 949	2 214	27.9 (26.9, 28.8)	9 681	3 023	31.2 (30.3, 32.1)	3.4 (2.0, 4.7)	14 654	5 613	38.3 (37.5, 39.1)	7.1 (5.9, 8.3)
Grade 4
Boy	3 911	1 413	36.1 (34.6, 37.6)	4 680	1 743	37.2 (35.9, 38.6)		7 896	3 445	43.6 (42.5, 44.7)
Girl	3 242	1 369	42.2 (40.5, 43.9)	4 009	1 833	45.7 (44.2, 47.3)		6 660	3 389	50.9 (49.7, 52.1)
Subtotal	7 153	2 782	38.9 (37.8, 40.0)	8 689	3 576	41.2 (40.1, 42.2)	2.3 (0.7, 3.8)	14 556	6 834	46.9 (46.1, 47.8)	5.8 (4.5, 7.1)
Grade 5
Boy	3 357	1 396	41.6 (39.9, 43.3)	4 231	1 954	46.2 (44.7, 47.7)		7 608	4 006	52.7 (51.5, 53.8)
Girl	2 795	1 479	52.9 (51.1, 54.8)	3 486	2 004	57.5 (55.8, 59.1)		6 661	4 150	62.3 (61.1, 63.5)
Subtotal	6 152	2 875	46.7 (45.5, 48.0)	7 717	3 958	51.3 (50.2, 52.4)	4.6 (2.9, 6.2)	14 269	8 156	57.2 (56.3, 58.0)	5.9 (4.5, 7.3)
Grade 6
Boy	3 420	1 813	53.0 (51.3, 54.7)	3 624	1 911	52.7 (51.1, 54.4)		7 140	4 231	59.3 (58.1, 60.4)
Girl	2 840	1 856	65.4 (63.6, 67.1)	3 069	2 035	66.3 (64.6, 68.0)		5 982	4 169	69.7 (68.5, 70.9)
Subtotal	6 260	3 669	58.6 (57.4, 59.8)	6 693	3 946	59.0 (57.8, 60.1)	0.3 (-1.4, 2.1)	13 122	8 400	64.0 (63.2, 64.8)	5.1 (3.6, 6.5)
Grade 1-6
Boy	24 793	7 038	28.4 (27.8, 28.9)	28 827	9 303	32.3 (31.7, 32.8)		45 182	18 003	39.8 (39.4, 40.3)
Girl	20 501	6 902	33.7 (33.0, 34.3)	24 095	9 273	38.5 (37.9, 39.1)		39 806	17 516	44.0 (43.5, 44.5)
Total	45 294	13 940	30.8 (30.4, 31.2)	52 922	18 576	35.1 (34.7, 35.5)	4.3 (3.7, 4.9)	84 988	35 519	41.8 (41.5, 42.1)	6.7 (6.2, 7.2)

表1

表2

2019—2024年不同年级、不同性别小学生等效球镜度数"

Items	2019		2020		2024
Items	n	Spherical equivalent/D	n	Spherical equivalent/D	n	Spherical equivalent/D
Grade 1
Boy	5 081	0.09 (0.06, 0.11)	5 625	-0.16 (-0.19, -0.13)	7 027	0.06 (0.03, 0.08)
Girl	3 929	0.10 (0.07, 0.13)	4 694	-0.13 (-0.16, -0.10)	6 444	0.11 (0.08, 0.14)
Subtotal	9 010	0.09 (0.07, 0.11)	10 319	-0.15 (-0.17, -0.12)	13 471	0.08 (0.06, 0.10)
Grade 2
Boy	4 743	-0.10 (-0.13, -0.08)	5 429	-0.32 (-0.35, -0.28)	7 810	-0.18 (-0.21, -0.16)
Girl	4 027	-0.14 (-0.17, -0.11)	4 394	-0.34 (-0.37, -0.30)	7 106	-0.18 (-0.21, -0.15)
Subtotal	8 770	-0.12 (-0.14, -0.10)	9 823	-0.32 (-0.35, -0.30)	14 916	-0.18 (-0.20, -0.16)
Grade 3
Boy	4 281	-0.38 (-0.42, -0.35)	5 238	-0.56 (-0.59, -0.52)	7 701	-0.49 (-0.51, -0.46)
Girl	3 668	-0.43 (-0.47, -0.39)	4 443	-0.65 (-0.69, -0.61)	6 953	-0.55 (-0.58, -0.51)
Subtotal	7 949	-0.40 (-0.43, -0.38)	9 681	-0.60 (-0.63, -0.58)	14 654	-0.51 (-0.54, -0.49)
Grade 4
Boy	3 911	-0.66 (-0.70, -0.62)	4 680	-0.84 (-0.88, -0.79)	7 896	-0.75 (-0.78, -0.72)
Girl	3 242	-0.79 (-0.84, -0.74)	4 009	-1.00 (-1.04, -0.95)	6 660	-0.91 (-0.94, -0.87)
Subtotal	7 153	-0.72 (-0.75, -0.69)	8 689	-0.91 (-0.94, -0.88)	14 556	-0.82 (-0.85, -0.80)
Grade 5
Boy	3 357	-0.86 (-0.91, -0.81)	4 231	-1.10 (-1.15, -1.05)	7 608	-1.06 (-1.10, -1.03)
Girl	2 795	-1.08 (-1.14, -1.03)	3 486	-1.38 (-1.43, -1.32)	6 661	-1.29 (-1.33, -1.24)
Subtotal	6 152	-0.96 (-1.00, -0.92)	7 717	-1.23 (-1.26, -1.19)	14 269	-1.17 (-1.20, -1.14)
Grade 6
Boy	3 420	-1.25 (-1.30, -1.19)	3 624	-1.34 (-1.40, -1.28)	7 140	-1.36 (-1.41, -1.32)
Girl	2 840	-1.49 (-1.55, -1.42)	3 069	-1.68 (-1.74, -1.62)	5 982	-1.68 (-1.73, -1.63)
Subtotal	6 260	-1.36 (-1.40, -1.32)	6 693	-1.50 (-1.54, -1.45)	13 122	-1.51 (-1.54, -1.48)
Grade 1-6
Boy	24 793	-0.46 (-0.48, -0.44)	28 827	-0.66 (-0.67, -0.64)	45 182	-0.63 (-0.64, -0.62)
Girl	20 501	-0.56 (-0.58, -0.54)	24 095	-0.79 (-0.80, -0.77)	39 806	-0.73 (-0.74, -0.71)
Total	45 294	-0.51 (-0.52, -0.49)	52 922	-0.72 (-0.73, -0.70)	84 988	-0.68 (-0.69, -0.67)

表2

参考文献 36

1	Liang J , Pu Y , Chen J , et al. Global prevalence, trend and projection of myopia in children and adolescents from 1990 to 2050: A comprehensive systematic review and meta-analysis[J]. Br J Ophthalmol, 2025, 109 (3): 362- 371. doi: 10.1136/bjo-2024-325427
2	国家疾控局. 国家疾控局积极推进儿童青少年近视防控近视率呈下降趋势[EB/OL]. (2024-03-13)[2025-05-13]. https://www.ndcpa.gov.cn/jbkzzx/c100008/common/content/content_1764617954927783936.html.
3	Haarman AEG , Enthoven CA , Tideman JWL , et al. The complications of myopia: A review and meta-analysis[J]. Invest Ophthalmol Vis Sci, 2020, 61 (4): 49. doi: 10.1167/iovs.61.4.49
4	Ha A , Lee YJ , Lee M , et al. Digital screen time and myopia: A systematic review and dose-response meta-analysis[J]. JAMA Netw Open, 2025, 8 (2): e2460026. doi: 10.1001/jamanetworkopen.2024.60026
5	Xiong S , Sankaridurg P , Naduvilath T , et al. Time spent in outdoor activities in relation to myopia prevention and control: A meta-analysis and systematic review[J]. Acta Ophthalmol, 2017, 95 (6): 551- 566. doi: 10.1111/aos.13403
6	Xiang M , Zhang Z , Kuwahara K . Impact of COVID-19 pandemic on children and adolescents' lifestyle behavior larger than expected[J]. Prog Cardiovasc Dis, 2020, 63 (4): 531- 532. doi: 10.1016/j.pcad.2020.04.013
7	Ma M , Xiong S , Zhao S , et al. COVID-19 home quarantine accelerated the progression of myopia in children aged 7 to 12 years in China[J]. Invest Ophthalmol Vis Sci, 2021, 62 (10): 37. doi: 10.1167/iovs.62.10.37
8	Kägi-Braun N , Hedin L , Cassel S , et al. Physical activity and screen time trends in Swedish youth: The generation pep study 2018-2023[J]. Acta Paediatr, 2025, 114 (10): 2589- 2602. doi: 10.1111/apa.70146
9	Orgilés M , Amorós-Reche V , Francisco R , et al. Beyond the pandemic: Tracing the evolution of activity, screen time, and sleep in European children over 3 years[J]. Eur J Pediatr, 2025, 184 (10): 629. doi: 10.1007/s00431-025-06458-1
10	国家卫生健康委员会. 《儿童青少年近视防控适宜技术指南(更新版)》及解读[EB/OL]. (2021-10-13)[2026-01-16]. https://www.gov.cn/xinwen/2021-10/13/content_5642345.htm.
11	王红星, 徐文武, 王金玲. 阜阳市颍泉区2022—2024年中小学生筛查性近视情况及影响因素分析[J]. 安徽预防医学杂志, 2025, 31 (4): 339- 344.
12	国家卫生健康委员会. 去年全国儿童青少年近视率53.6%[EB/OL]. (2019-04-29)[2026-01-08]. https://jiankang.cctv.com/2019/04/29/ARTI9HBa9IQ2vBCreF4OCYvI190429.shtml.
13	徐李莎, 黄烨, 吴汶灿, 等. 河南省中小学生2019—2020年近视队列研究结果[J]. 中国学校卫生, 2023, 44 (12): 1814-1818, 1823.
14	梁艺, 王早霞, 胡池, 等. 2019—2022年宜昌市中小学生常见病监测结果分析[J]. 公共卫生与预防医学, 2025, 36 (4): 98- 101.
15	Yotsukura E , Torii H , Inokuchi M , et al. Current prevalence of myopia and association of myopia with environmental factors among schoolchildren in Japan[J]. JAMA Ophthalmol, 2019, 137 (11): 1233- 1239. doi: 10.1001/jamaophthalmol.2019.3103
16	Lim DH , Han J , Chung TY , et al. The high prevalence of myopia in Korean children with influence of parental refractive errors: The 2008-2012 Korean National Health and Nutrition Examination Survey[J]. PLoS One, 2018, 13 (11): e0207690. doi: 10.1371/journal.pone.0207690
17	Santiago HC , Ortiz K , Rivera A , et al. Prevalence of refractive errors in children of Puerto Rico[J]. Int J Ophthalmol, 2023, 16 (3): 434- 441. doi: 10.18240/ijo.2023.03.15
18	Hönekopp A , Tommes LM , Doebler P , et al. Myopia prevalence, refractive status and uncorrected myopia among primary and secondary school students in Germany[J]. Front Med, 2024, 11, 1483069. doi: 10.3389/fmed.2024.1483069
19	Pärssinen O , Franssila ML , Nordhausen K , et al. The prevalence of myopia in Finnish conscripts has not increased in recent decades and is lower than in many east and Southeast Asian countries[J]. Invest Ophthalmol Vis Sci, 2025, 66 (12): 10. doi: 10.1167/iovs.66.12.10
20	Morgan IG , Ohno-Matsui K , Saw SM . Myopia[J]. Lancet, 2012, 379 (9827): 1739- 1748. doi: 10.1016/S0140-6736(12)60272-4
21	Morgan IG , Rose KA . Myopia and international educational performance[J]. Ophthalmic Physiol Opt, 2013, 33 (3): 329- 338. doi: 10.1111/opo.12040
22	Meguro A , Yamane T , Takeuchi M , et al. Genome-wide association study in Asians identifies novel loci for high myopia and highlights a nervous system role in its pathogenesis[J]. Ophthalmology, 2020, 127 (12): 1612- 1624. doi: 10.1016/j.ophtha.2020.05.014
23	Fan Q , Verhoeven VJM , Wojciechowski R , et al. Meta-analysis of gene-environment-wide association scans accounting for education level identifies additional loci for refractive error[J]. Nature Commun, 2016, 7, 11008. doi: 10.1038/ncomms11008
24	韩霄, 汪静, 陈辉, 等. 2019—2021年北京市东城区小学生筛查性近视及屈光状态分析[J]. 中国预防医学杂志, 2023, 24 (4): 388- 392.
25	Chang P , Zhang B , Lin L , et al. Comparison of myopic progression before, during, and after COVID-19 lockdown[J]. Ophthalmology, 2021, 128 (11): 1655- 1657. doi: 10.1016/j.ophtha.2021.03.029
26	Zhang XJ , Zhang Y , Kam KW , et al. Prevalence of myopia in children before, during, and after COVID-19 restrictions in Hong Kong[J]. JAMA Netw Open, 2023, 6 (3): e234080. doi: 10.1001/jamanetworkopen.2023.4080
27	Alvarez-Peregrina C , Martinez-Perez C , Villa-Collar C , et al. Impact of COVID-19 home confinement in children's refractive errors[J]. Int J Environ Res Public Health, 2021, 18 (10): 5347.
28	Darko-Takyi C , Mills TW , Boadi-Kusi SB , et al. Association between near visual display device usage and the eye's accommodation and vergence parameters: A cross-sectional study of high school children in Cape Coast, Ghana[J]. BMJ Public Health, 2025, 3 (2): e003041. doi: 10.1136/bmjph-2025-003041
29	Wang J , Li Y , Musch D , et al. Progression of myopia in school-aged children after COVID-19 home confinement[J]. JAMA Ophthalmol, 2021, 139 (3): 293- 300. doi: 10.1001/jamaophthalmol.2020.6239
30	Zhang J , Li Z , Ren J , et al. Prevalence of myopia: A large-scale population-based study among children and adolescents in Weifang, China[J]. Front Public Health, 2022, 10, 924566. doi: 10.3389/fpubh.2022.924566
31	Gao J , Meng L , Lv X , et al. Analysis of refractive development characteristics in school-age children based on biometric measurements: A cross-sectional study involving 12 025 primary school students from Xingtai City[J]. Front Public Health, 2025, 13, 1660018.
32	Guo L , Yang J , Mai J , et al. Prevalence and associated factors of myopia among primary and middle school-aged students: A school-based study in Guangzhou[J]. Eye, 2016, 30 (6): 796- 804.
33	Tian L , Zhu M , Song Y , et al. The prevalence of myopia and eye health behaviors among 3 to 18 years: A cross-sectional survey study[J]. BMC Public Health, 2025, 25 (1): 1688.
34	Zhang X , Wang J , Weng Y , et al. Myopia prevalence among primary school students across different districts in Guangzhou: Insights from a large-scale school-based screening[J]. BMC Public Health, 2025, 25 (1): 3615.
35	Sankaridurg P , He X , Naduvilath T , et al. Comparison of noncycloplegic and cycloplegic autorefraction in categorizing refractive error data in children[J]. Acta Ophthalmol, 2017, 95 (7): e633- e640.
36	徐梓航, 胡媛媛, 温莹, 等. 3种方法界定儿童青少年近视检出率及其一致性评价[J]. 中国学校卫生, 2023, 44 (5): 747-750, 755.

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2019—2024年以行政辖区小学生人群为基础的近视情况调查

A population-based survey of myopia on primary school students in an administrative district, 2019 to 2024

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