偏移孔径自适应光学眼底镜中细胞对比度的起源。
Origin of cell contrast in offset aperture adaptive optics ophthalmoscopy.
出版信息
Opt Lett. 2020 Feb 15;45(4):840-843. doi: 10.1364/OL.382589.
Abstract
Offset aperture and split detector imaging are variants of adaptive optics scanning ophthalmoscopy recently introduced to improve the image contrast of retinal cells. Unlike conventional confocal scanning ophthalmoscopy, these approaches collect light laterally decentered from the optical axis. A complete explanation of how these methods enhance contrast has not been described. Here, we provide an optical model with supporting in vivo data that show contrast is generated from spatial variations in the refractive index as it is in phase contrast microscopy. A prediction of this model is supported by experimental data that show contrast is optimized when the detector is placed conjugate with a deeper backscattering screen such as the retinal pigment epithelium and choroid, rather than with the layer being imaged as in conventional confocal imaging. This detection strategy provides a substantial improvement in the contrast these new methods can produce.
摘要
离轴孔径和分束探测器成像是最近引入的自适应光学扫描检眼镜的两种变体,用于提高视网膜细胞的图像对比度。与传统的共焦扫描检眼镜不同,这些方法从光轴横向收集偏离的光。这些方法如何增强对比度的完整解释尚未描述。在这里,我们提供了一个带有支持性体内数据的光学模型,表明对比度是由折射率的空间变化产生的,就像相差显微镜一样。该模型的一个预测得到了实验数据的支持,该数据表明,当探测器与更深的后向散射屏(如视网膜色素上皮和脉络膜)共轭放置时,而不是像传统的共焦成像那样与正在成像的层共轭放置时,对比度达到最佳。这种检测策略可显著提高这些新方法所能产生的对比度。
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