利用随机散斑照明提高三维荧光显微镜的轴向和横向分辨率。

Improving the axial and lateral resolution of three-dimensional fluorescence microscopy using random speckle illuminations.

作者信息

Negash Awoke, Labouesse Simon, Sandeau Nicolas, Allain Marc, Giovannini Hugues, Idier Jérôme, Heintzmann Rainer, Chaumet Patrick C, Belkebir Kamal, Sentenac Anne

出版信息

J Opt Soc Am A Opt Image Sci Vis. 2016 Jun 1;33(6):1089-94. doi: 10.1364/JOSAA.33.001089.

DOI:10.1364/JOSAA.33.001089

PMID:27409435

Abstract

We consider a fluorescence microscope in which several three-dimensional images of a sample are recorded for different speckle illuminations. We show, on synthetic data, that by summing the positive deconvolution of each speckle image, one obtains a sample reconstruction with axial and transverse resolutions that compare favorably to that of an ideal confocal microscope.

摘要

我们考虑一种荧光显微镜，其中针对不同的散斑照明记录样品的几个三维图像。我们在合成数据上表明，通过对每个散斑图像的正向反卷积求和，可以得到一个样品重建，其轴向和横向分辨率与理想共聚焦显微镜的分辨率相比具有优势。

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利用随机散斑照明提高三维荧光显微镜的轴向和横向分辨率。

Improving the axial and lateral resolution of three-dimensional fluorescence microscopy using random speckle illuminations.

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利用随机散斑照明提高三维荧光显微镜的轴向和横向分辨率。

Improving the axial and lateral resolution of three-dimensional fluorescence microscopy using random speckle illuminations.

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出版信息

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