可见光相干断层扫描的水波数校准。

Water wavenumber calibration for visible light optical coherence tomography.

机构信息

University of California Davis, Department of Biomedical Engineering, Davis, California, United States.

University of California Davis, School of Medicine, Department of Ophthalmology and Vision Science,, United States.

出版信息

J Biomed Opt. 2020 Sep;25(9). doi: 10.1117/1.JBO.25.9.090501.

DOI:10.1117/1.JBO.25.9.090501

PMID:32935500

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7490762/

Abstract

SIGNIFICANCE

Visible light optical coherence tomography (OCT) is emerging for spectroscopic and ultrahigh resolution imaging, but challenges remain. Depth-dependent dispersion limits retinal image quality and current correction approaches are cumbersome. Inconsistent group refractive indices during image reconstruction also limit reproducibility.

AIM

To introduce and evaluate water wavenumber calibration (WWC), which corrects depth-dependent dispersion and provides an accurate depth axis in water.

APPROACH

Enabled by a visible light OCT spectrometer configuration with a 3- to 4-dB sensitivity roll-off over 1 mm in air across a 90-nm bandwidth, we determine the spectral phase of a 1-mm water cell, an affine function of water wavenumber. Via WWC, we reconstruct visible light OCT human retinal images with 1.3-μm depth resolution in water.

RESULTS

Images clearly reveal Bruch's membrane, inner plexiform layer lamination, and a thin nerve fiber layer in the temporal parafovea. WWC halves the processing time, while achieving the same image definition as an assumption-free gold standard approach, suggesting that water wavenumber is a suitable proxy for tissue wavenumber. WWC also provides a depth axis in water without explicitly assuming a group refractive index.

CONCLUSIONS

WWC is a simple method that helps to realize the full potential of visible light OCT.

摘要

意义

可见光光学相干断层扫描（OCT）正逐渐应用于光谱学和超高分辨率成像，但仍存在挑战。深度相关的色散限制了视网膜图像质量，而当前的校正方法繁琐。在图像重建过程中折射率组不一致也限制了可重复性。

目的

引入并评估水波数校准（WWC），该方法可校正深度相关的色散，并在水中提供准确的深度轴。

方法

借助可见光谱光 OCT 分光计配置，在 90nm 带宽内，空气中的灵敏度在 1mm 处下降 3-4dB，我们确定了 1mm 厚的水腔的光谱相位，这是水波数的仿射函数。通过 WWC，我们在水中以 1.3μm 的深度分辨率重建了可见光谱光 OCT 人视网膜图像。

结果

图像清晰地揭示了布鲁赫膜、内丛状层分层和颞侧旁中心凹的薄神经纤维层。WWC 将处理时间缩短了一半，同时达到了无假设黄金标准方法相同的图像清晰度，这表明水波数是组织波数的合适替代物。WWC 还在水中提供了一个深度轴，而无需明确假设群折射率。

结论

WWC 是一种简单的方法，可以帮助充分发挥可见光谱光 OCT 的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/33eb/7490762/1face4f96a31/JBO-025-090501-g001.jpg

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可见光相干断层扫描的水波数校准。

Water wavenumber calibration for visible light optical coherence tomography.

机构信息

出版信息

SIGNIFICANCE

AIM

APPROACH

RESULTS

CONCLUSIONS

意义

目的

方法

结果

结论

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