胎儿期、婴儿期和幼儿期的生长发育与眼生物测量学的关系。

Growth in foetal life, infancy, and early childhood and the association with ocular biometry.

机构信息

Department of Ophthalmology, Erasmus MC, University Medical Centre, Rotterdam, the Netherlands.

Department of Epidemiology, Erasmus MC, University Medical Centre, Rotterdam, the Netherlands.

出版信息

Ophthalmic Physiol Opt. 2019 Jul;39(4):245-252. doi: 10.1111/opo.12630.

DOI:10.1111/opo.12630

PMID:31236981

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6618159/

Abstract

PURPOSE

Ocular biometry varies within groups of emmetropic, hyperopic or myopic children. The aim of this study was to quantify the effect of foetal and infant growth on ocular biometry in early childhood, to determine the most important period for this association, and to examine genetic overlap with height and birth weight.

METHODS

5931 children (50.1% girls) from a population-based prospective birth cohort study underwent intra-uterine and infant growth measurements at second and third trimester, and from birth to 72 months. An ophthalmic examination including axial length (mm) and corneal radius of curvature (mm) was performed at 6 years of age. The associations between prenatal and postnatal growth variables and axial length and corneal radius of curvature were assessed with conditional linear regression analyses. Weighted genetic risk scores for birth weight and height were calculated and causality was tested with Mendelian randomisation.

RESULTS

Weight and length from mid-pregnancy to 2 years of age were most important prognostic factors for axial length and corneal radius of curvature at age 4.9-9 years (mean 6.2 years S.D. 0.5). For height (Standard deviation score), the association with axial length and corneal radius of curvature was highest for the measurement at 12 months (β 0.171 p < 0.001 and 0.070 p < 0.001). The genetic height and birth weight risk scores were both significantly associated with ocular biometry.

CONCLUSIONS

Larger neonates had longer axial length and greater corneal radius of curvature. Growth during pregnancy and 2 years postnatally is the most important period underlying this association and may be partly genetically determined by genes associated with height.

摘要

目的

正视、远视或近视儿童群体的眼生物测量值存在差异。本研究旨在量化胎儿和婴儿期生长对儿童早期眼生物测量的影响，确定这种关联的最重要时期，并研究与身高和出生体重的遗传重叠。

方法

5931 名（50.1%为女性）来自基于人群的前瞻性出生队列研究的儿童，在妊娠中期和晚期以及出生到 72 个月时进行宫内和婴儿生长测量。在 6 岁时进行眼科检查，包括眼轴长度（mm）和角膜曲率半径（mm）。使用条件线性回归分析评估产前和产后生长变量与眼轴长度和角膜曲率半径之间的关联。计算出生体重和身高的加权遗传风险评分，并使用孟德尔随机化检验因果关系。

结果

从中孕期到 2 岁的体重和长度是 4.9-9 岁（平均 6.2 岁，标准差 0.5）时眼轴长度和角膜曲率半径的最重要预后因素。对于身高（标准差评分），与眼轴长度和角膜曲率半径的关联在 12 个月时最高（β 0.171，p<0.001 和 0.070，p<0.001）。遗传身高和出生体重风险评分均与眼生物测量显著相关。

结论

较大的新生儿眼轴较长，角膜曲率半径较大。妊娠和出生后 2 年的生长是这种关联的最重要时期，可能部分由与身高相关的基因遗传决定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bd75/6618159/49505d371481/OPO-39-245-g001.jpg

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胎儿期、婴儿期和幼儿期的生长发育与眼生物测量学的关系。

Growth in foetal life, infancy, and early childhood and the association with ocular biometry.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

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方法

结果

结论

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