Dynamic in vivo mapping of the gradient refractive index and strain distribution of the human lens under accommodative stress

IF 3 2区医学 Q1 OPHTHALMOLOGY

Experimental eye research Pub Date : 2025-03-11 DOI:10.1016/j.exer.2025.110332

Sabine Kling , Vahoura Tahsini , Farhad Hafezi

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Abstract

The mechanical properties and refractive index (RI) distribution within the human crystalline lens are essential for understanding accommodation and age-related changes in the lens. However, there is limited knowledge about how these properties change in vivo with accommodative demand and aging. Previous methods lacked the ability to simultaneously measure both RI and mechanical strain in the lens, limiting their ability to capture the full complexity of the lens' behavior. To address this gap, we measured the spatial distribution of the RI and mechanical strain in the lenses of six healthy participants (aged 24–45 years) using optical coherence tomography (OCT) under three accommodative demands (0, −2, and −4 diopters). A phase-based signal processing algorithm was developed to compute the RI at each pixel of the OCT B-scans, while instantaneous and accumulated strains were used to assess the lens's mechanical properties during micro-fluctuations.

Our results indicated an axial RI gradient, with the highest RI values in the posterior half of the lens. The RI did not significantly change with age or accommodative demand in participants under 45. However, the instantaneous strain, representing the deformation speed, decreased with age, while the accumulated strain during micro-fluctuations increased with higher accommodative demands. No correlation was observed between the RI and mechanical strain distribution within the lens.

These findings suggest that OCT is a promising high-resolution tool for in vivo optomechanical characterization of the crystalline lens, offering valuable patient-specific data. OCT could be instrumental in future studies of lenticular changes during emmetropization and myopization.

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调节应力下人体晶状体梯度折射率和应变分布的动态体内映射。

人类晶状体的力学特性和折射率分布对于理解晶状体的适应性和年龄相关变化至关重要。然而，关于这些特性如何在体内随着适应性需求和衰老而变化的知识有限。以前的方法缺乏同时测量透镜中的RI和机械应变的能力，限制了它们捕捉透镜行为的全部复杂性的能力。为了解决这一差距，我们使用光学相干断层扫描（OCT）测量了六名健康参与者（24-45岁）在三种调节要求（0、-2和-4屈光度）下晶状体的RI和机械应变的空间分布。开发了一种基于相位的信号处理算法来计算OCT b扫描每个像素的RI，同时使用瞬时应变和累积应变来评估微波动时透镜的力学特性。我们的结果显示一个轴向的RI梯度，在晶状体的后半部有最高的RI值。在45岁以下的参与者中，RI随年龄或适应性需求没有显著变化。而代表变形速度的瞬时应变随龄期的增加而减小，而微波动期间的累积应变随着调节要求的提高而增加。晶状体内的机械应变分布与RI之间没有相关性。这些发现表明，OCT是一种有前途的高分辨率工具，可用于晶状体的体内光学力学表征，提供有价值的患者特异性数据。OCT可以在未来研究正视和近视过程中晶状体的变化。

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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来源期刊

Experimental eye research 医学-眼科学

CiteScore

6.80

自引率

5.90%

发文量

323

审稿时长

66 days

期刊介绍： The primary goal of Experimental Eye Research is to publish original research papers on all aspects of experimental biology of the eye and ocular tissues that seek to define the mechanisms of normal function and/or disease. Studies of ocular tissues that encompass the disciplines of cell biology, developmental biology, genetics, molecular biology, physiology, biochemistry, biophysics, immunology or microbiology are most welcomed. Manuscripts that are purely clinical or in a surgical area of ophthalmology are not appropriate for submission to Experimental Eye Research and if received will be returned without review.