The Relationship Between Anthropometric Z-Score Measurements and Ocular Structures in Turkish Children.

Erkan Bulut, Ahmet Kürşad Sakallioğlu, Özlem Dayi, Goksu Alacamli
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Abstract

Objective (Aim): This study explores the contact between anthropometric Z-score values and ocular parameters in children. Recent studies investigated the relationship, and contact between anthropometric measurements and ocular parameters in children, and height, weight, body mass index, and percentile curves are mostly used as anthropometric data. However, today, different scoring systems such as "Z-score" classify anthropometric values. Methods: Height and body mass index Z-scores were calculated for 725 children. Biometric and refractive measurements of all children were noted. For different reference values, those with a Z-score below the negative value of the reference were defined as a low Z-score, those between the negative and positive value of the reference were defined as a normal Z-score, those with a Z-score greater than the positive value of the reference were defined as a high Z-score. The mean ocular measurement results in the low, normal, and high Z-score groups were compared, and they were pointed to reach the reference value in both negative and positive sides which created the foremost critical contrast between the groups. Results: For a value of "-1" and "+1.5" in the height Z-score, from low to normal and from there to high Z-score group, axial length, and average corneal radius increased, and average corneal power decreased significantly. Anterior chamber depth increased from normal to high Z-score group, but no critical distinction was made between low and normal Z-score groups. Moreover, no critical distinction was observed in spherical equivalent refraction, central corneal thickness for height, and all values of body mass index. Conclusion: Considering a Z-score value of "-1" and "+1.5" as a reference value in children and anticipating the changes that may happen in the ocular structures of children at both ends of the Z-score, it may be useful to understand the effect of body development on ocular development more. Abbreviations: AL = Axial Length, ACD = Anterior Chamber Depth, BMI = Body Mass Index, NCHS = The United States National Center for Health Statistics, WHO = World Health Organization, NFHS 2 = National Family Health Survey 2, SER = Spherical Equivalent Refraction, CR = Average Corneal Radius, CP = Average Corneal Power, CCT = Central Corneal Thickness, HFAsZ = Height for Age Z-Score, BMIsZ = BMI for Age Z-Score, L = Low Z-score, N = Normal Z-score, H = High Z-score.

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土耳其儿童的人体测量 Z 值与眼部结构之间的关系。
目的(Aim):本研究探讨了儿童人体测量 Z 值与眼部参数之间的联系。最近的研究调查了儿童人体测量值与眼部参数之间的关系和联系,身高、体重、体重指数和百分位曲线大多被用作人体测量数据。然而,如今有不同的评分系统(如 "Z-score")对人体测量值进行分类。方法:计算 725 名儿童的身高和体重指数 Z 值。记录所有儿童的生物测量和屈光测量结果。对于不同的参考值,Z 值低于参考值负值的被定义为低 Z 值,介于参考值负值和正值之间的被定义为正常 Z 值,Z 值大于参考值正值的被定义为高 Z 值。比较了低 Z 值组、正常 Z 值组和高 Z 值组的平均眼部测量结果,发现它们的负值和正值都达到了参考值,这也是各组之间最关键的对比。结果在身高 Z 值为"-1 "和 "+1.5 "的情况下,从低 Z 值组到正常组,再从正常组到高 Z 值组,轴长和平均角膜半径都显著增加,而平均角膜力则显著下降。前房深度从正常 Z 值组到高 Z 值组都有所增加,但低 Z 值组和正常 Z 值组之间没有明显区别。此外,在球面等效屈光度、角膜中央厚度(身高)和所有体重指数值方面也没有观察到临界差异。结论将儿童的 Z 值"-1 "和 "+1.5 "作为参考值,并预测儿童眼部结构在 Z 值两端可能发生的变化,可能有助于进一步了解身体发育对眼部发育的影响。缩写:AL = 轴长,ACD = 前房深度,BMI = 体重指数,NCHS = 美国国家卫生统计中心,WHO = 世界卫生组织,NFHS 2 = 全国家庭健康调查 2、SER = 球面等效屈光度,CR = 平均角膜半径,CP = 平均角膜力量,CCT = 角膜中央厚度,HFAsZ = 年龄 Z 值身高,BMIsZ = 年龄 Z 值体重指数,L = 低 Z 值,N = 正常 Z 值,H = 高 Z 值。
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