Characterization of Directional Reflectance in Corneal Tissue: A Comprehensive Optical Coherence Tomography Analysis.

IF 2.6 3区医学 Q2 OPHTHALMOLOGY

Translational Vision Science & Technology Pub Date : 2025-04-01 DOI:10.1167/tvst.14.4.7

Jad F Assaf, Jiachi Hong, Yan Li, David Huang

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引用次数: 0

Abstract

Purpose: To characterize the directional reflectance properties of the cornea using optical coherence tomography (OCT) imaging and develop a mathematical model describing corneal reflectance as a function of depth and incidence angle across different corneal layers.

Methods: A retrospective analysis was conducted on OCT scans from normal subjects using the Visionix Avanti OCT system (840 nm). Reflectance values for the epithelium, Bowman's layer, stroma, and endothelium/Descemet's membrane were extracted and analyzed as functions of incidence angle and corneal depth. Reflectance distributions were assessed for normality. Exponential functions were fitted to the mean and 97th percentile reflectance data to model directional reflectance for each corneal layer.

Results: Reflectance values exhibited non-normal leptokurtic distributions with right-tailed skewness, requiring non-parametric methods for percentile calculations. The exponential model incorporating angular dependence achieved R² values of 0.987 and 0.963 for mean and 97th percentile reflectance, respectively. The mean reflectance of the epithelium was modeled by a single exponential function, with half-reflectance angles of 15.9° to 26.6°. The stromal layers required two exponential components, with the anterior stroma exhibiting the highest reflectance and most pronounced directionality (half-reflectance angle of 0.17°). The 97th percentile reflectance differed, with higher reflectance values in the middle and posterior stroma. No statistically significant age or gender related variability in reflectance was measured.

Conclusions: This study provides a detailed mathematical model of corneal directional reflectance, highlighting the importance of incidence angle and layer depth in OCT image analysis.

Translational relevance: The developed cornea reflectance model may improve OCT-based diagnostics by identifying early microstructural changes, aiding in the diagnosis and management of corneal diseases.

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角膜组织的定向反射特性：综合光学相干断层扫描分析。

目的：利用光学相干断层扫描（OCT）成像技术表征角膜的定向反射特性，并建立描述角膜反射率随不同角膜层深度和入射角函数的数学模型。方法：使用Visionix Avanti OCT系统（840 nm）对正常受试者的OCT扫描进行回顾性分析。提取上皮、鲍曼层、间质和内皮/Descemet膜的反射率值，并分析其随入射角和角膜深度的变化。对反射率分布进行正态性评估。对平均和第97百分位反射率数据拟合指数函数来模拟每个角膜层的方向反射率。结果：反射率值呈现非正态细峰分布，具有右尾偏度，需要非参数方法进行百分位数计算。考虑角度相关性的指数模型的平均反射率和第97百分位反射率的R²值分别为0.987和0.963。上皮的平均反射率采用单指数函数建模，半反射率为15.9°~ 26.6°。基质层需要两个指数分量，其中前基质具有最高的反射率和最明显的方向性（半反射率为0.17°）。第97百分位反射率不同，中间和后部基质的反射率值较高。在反射率方面没有统计上显著的年龄或性别差异。结论：本研究提供了一个详细的角膜定向反射率数学模型，突出了入射角和层深在OCT图像分析中的重要性。翻译相关性：开发的角膜反射模型可以通过识别早期显微结构变化来改善基于oct的诊断，有助于角膜疾病的诊断和治疗。

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

Translational Vision Science & Technology Engineering-Biomedical Engineering

CiteScore

5.70

自引率

3.30%

发文量

346

审稿时长

25 weeks

期刊介绍： Translational Vision Science & Technology (TVST), an official journal of the Association for Research in Vision and Ophthalmology (ARVO), an international organization whose purpose is to advance research worldwide into understanding the visual system and preventing, treating and curing its disorders, is an online, open access, peer-reviewed journal emphasizing multidisciplinary research that bridges the gap between basic research and clinical care. A highly qualified and diverse group of Associate Editors and Editorial Board Members is led by Editor-in-Chief Marco Zarbin, MD, PhD, FARVO. The journal covers a broad spectrum of work, including but not limited to: Applications of stem cell technology for regenerative medicine, Development of new animal models of human diseases, Tissue bioengineering, Chemical engineering to improve virus-based gene delivery, Nanotechnology for drug delivery, Design and synthesis of artificial extracellular matrices, Development of a true microsurgical operating environment, Refining data analysis algorithms to improve in vivo imaging technology, Results of Phase 1 clinical trials, Reverse translational ("bedside to bench") research. TVST seeks manuscripts from scientists and clinicians with diverse backgrounds ranging from basic chemistry to ophthalmic surgery that will advance or change the way we understand and/or treat vision-threatening diseases. TVST encourages the use of color, multimedia, hyperlinks, program code and other digital enhancements.