Ahmed Shaiban, Son Taeyoon, Ma Guangying, Yao Xincheng
University of Illinois Chicago, Department of Biomedical Engineering, Chicago, Illinois, United States.
University of Illinois Chicago, Department of Ophthalmology and Visual Sciences, Chicago, Illinois, United States.
Neurophotonics. 2025 Jan;12(1):015005. doi: 10.1117/1.NPh.12.1.015005. Epub 2025 Jan 27.
Stimulus-evoked intrinsic optical signal (IOS) changes in retinal photoreceptors are critical for functional optoretinography (ORG). Optical coherence tomography (OCT), with its depth-resolved imaging capability, has been actively explored for IOS imaging of retinal photoreceptors. However, recent OCT studies have reported conflicting results regarding light-induced changes in the photoreceptor outer segments (OSs), with both elongation and shrinkage being observed. These discrepancies may stem from the difficulty in reliably identifying OS boundaries, particularly the inner segment/outer segment (IS/OS) junction and OS tip, as well as potential confusion with subretinal space dynamics. Gaining a better understanding of these light-induced OS changes is essential for accurate interpretation of ORG measurements and for optimizing IOS imaging systems to enhance sensitivity.
We aim to develop a method for the reliable identification of OS boundaries and to verify light-induced photoreceptor OS shrinkage and subretinal space expansion.
We employed a polarization-resolved full-field swept-source optical coherence tomography system capable of sequentially capturing parallel-polarization and cross-polarization OCT signals. The parallel-polarization mode is optimized to detect ballistically reflected photons from well-defined retinal boundaries, such as the IS/OS junction and the photoreceptor tips, whereas cross-polarization primarily captures multiply scattered photons. This differentiation enables parallel-polarization OCT to minimize the interference from scattered photons, enhancing the precision of OCT band quantification.
Parallel-polarization OCT revealed photoreceptor OS shrinkage and subretinal space expansion in light conditions compared with dark conditions. Moreover, the overall outer retinal length appeared to swell under light. These observations were consistently confirmed in four healthy adult human subjects.
Parallel-polarization OCT provides a reliable method for identifying the IS/OS junction and OS tip, confirming light-induced photoreceptor OS shrinkage and subretinal space expansion.
视网膜光感受器中刺激诱发的内在光学信号(IOS)变化对于功能性视网膜电图(ORG)至关重要。光学相干断层扫描(OCT)凭借其深度分辨成像能力,已被积极探索用于视网膜光感受器的IOS成像。然而,最近的OCT研究报告了关于光诱导的光感受器外段(OS)变化的相互矛盾的结果,观察到既有伸长又有收缩。这些差异可能源于难以可靠地识别OS边界,特别是内段/外段(IS/OS)交界处和OS尖端,以及与视网膜下间隙动态的潜在混淆。更好地理解这些光诱导的OS变化对于准确解释ORG测量以及优化IOS成像系统以提高灵敏度至关重要。
我们旨在开发一种可靠识别OS边界的方法,并验证光诱导的光感受器OS收缩和视网膜下间隙扩张。
我们采用了一种偏振分辨全场扫频光学相干断层扫描系统,能够顺序捕获平行偏振和交叉偏振OCT信号。平行偏振模式经过优化,以检测来自明确视网膜边界(如IS/OS交界处和光感受器尖端)的弹道反射光子,而交叉偏振主要捕获多次散射光子。这种区分使平行偏振OCT能够最小化散射光子的干扰,提高OCT波段量化的精度。
与黑暗条件相比,平行偏振OCT显示在光照条件下光感受器OS收缩和视网膜下间隙扩张。此外,在光照下整个视网膜外层长度似乎肿胀。在四名健康成年人类受试者中一致证实了这些观察结果。
平行偏振OCT提供了一种可靠的方法来识别IS/OS交界处和OS尖端,证实了光诱导的光感受器OS收缩和视网膜下间隙扩张。
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