Investigating the effects of simulated high altitude on colour discrimination.

IF 2 Q2 OPHTHALMOLOGY BMJ Open Ophthalmology Pub Date : 2024-11-07 DOI:10.1136/bmjophth-2024-001894

Siru Liu, Yuchen Wang, Xinli Yu, Jiaxi Li, Jun Zhou, Yuanhong Li, Zesong Wang, Chengkai Zhou, Jiaxing Xie, Anqi Guo, Xinzuo Zhou, Yi Ding, Xuemin Li, Li Ding

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Abstract

Purpose: To quantify changes in colour vision immediately after exposure to different altitudes of low-pressure hypoxia.

Methods: The study involved 35 healthy participants (ages 20-26). Colour vision was assessed using the Farnsworth-Munsell 100-Hue test at eight different altitudes (condition 1: ground, condition 2: 3500 m, condition 3: 3500 m after 40 min, condition 4: 4000 m, condition 5: 4000 m after 40 min, condition 6: 4500 m, condition 7: 4500 m after 40 min, condition 8: back to the ground). Data were analysed using Analysis of Variance (ANOVA), paired t-test, and χ² test .

Results: Total Error Score (TES) increased with altitude and hypoxia duration, with higher TES in condition 8 than in condition 1. There were significant TES differences between conditions 3 and 7, as well as 4 and 7. Friedman and repeated ANOVA tests revealed significant sector differences, with Blue-Yellow Partial Error Score (PES) greater than Red-Green PES, particularly on conditions 4, 5 and 8. Significant Red-Green PES differences were found between conditions 4 and 7, and Blue-Yellow PES between conditions 3 and 5, 7, 8. Tritan (Blue-Yellow) shift was most pronounced at high altitudes.

Conclusions: This experiment investigated acute low-pressure hypoxia's effects on colour vision, supplementing chronic hypoxia research. Increased altitudes and exposure duration worsen colour vision, with effects persisting post-recovery. Tritan axis loss is most significant under hypoxia.

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研究模拟高海拔对颜色辨别力的影响。

目的：量化暴露于不同高度的低压缺氧环境后立即出现的色觉变化：研究涉及 35 名健康参与者（20-26 岁）。在 8 个不同海拔高度（条件 1：地面；条件 2：3500 米；条件 3：40 分钟后 3500 米；条件 4：4000 米；条件 5：40 分钟后 4000 米；条件 6：4500 米；条件 7：40 分钟后 4500 米；条件 8：返回地面）使用 Farnsworth-Munsell 100 色调测试评估色觉。数据分析采用方差分析（ANOVA）、配对 t 检验和 χ2 检验：总误差分（TES）随着海拔高度和缺氧时间的延长而增加，条件 8 的总误差分高于条件 1。条件 3 和条件 7 之间以及条件 4 和条件 7 之间的总误差分有明显差异。弗里德曼方差分析和重复方差分析检验表明，蓝-黄部分误差分值（PES）比红-绿部分误差分值大，尤其是在第 4、5 和 8 种条件下。在条件 4 和 7 之间发现了明显的红绿部分误差分值差异，在条件 3 和 5、7、8 之间发现了明显的蓝黄部分误差分值差异。在高海拔地区，Tritan（蓝-黄）偏移最为明显：本实验研究了急性低压缺氧对色觉的影响，是对慢性缺氧研究的补充。海拔升高和暴露时间延长会使色觉恶化，影响在恢复后持续存在。在缺氧条件下，色轴损失最为显著。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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