Quantitative dSTORM superresolution microscopy

Resolution and Discovery Pub Date : 2022-11-21 DOI:10.1556/2051.2022.00093

Tibor Novák, Dániel Varga, P. Biró, B. B. H. Kovács, Hajnalka Majoros, T. Pankotai, Szilárd Szikora, J. Mihály, M. Erdélyi

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Abstract

Localization based superresolution technique provides the highest spatial resolution in optical microscopy. The final image is formed by the precise localization of individual fluorescent dyes, therefore the quantification of the collected data requires special protocols, algorithms and validation processes. The effects of labelling density and structured background on the final image quality were studied theoretically using the TestSTORM simulator. It was shown that system parameters affect the morphology of the final reconstructed image in different ways and the accuracy of the imaging can be determined. Although theoretical studies help in the optimization procedure, the quantification of experimental data raises additional issues, since the ground truth data is unknown. Localization precision, linker length, sample drift and labelling density are the major factors that make quantitative data analysis difficult. Two examples (geometrical evaluation of sarcomere structures and counting the γH2AX molecules in DNA damage induced repair foci) have been presented to demonstrate the efficiency of quantitative evaluation experimentally.

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定量dSTORM超分辨显微镜

基于定位的超分辨率技术为光学显微镜提供了最高的空间分辨率。最终的图像是由单个荧光染料的精确定位形成的，因此收集数据的量化需要特殊的协议、算法和验证过程。利用TestSTORM模拟器从理论上研究了标记密度和结构化背景对最终图像质量的影响。结果表明，系统参数以不同的方式影响最终重建图像的形貌，从而确定成像的精度。虽然理论研究有助于优化过程，但实验数据的量化带来了额外的问题，因为地面真实数据是未知的。定位精度、连接器长度、样品漂移和标记密度是定量数据分析困难的主要因素。两个例子(肌节结构的几何评价和DNA损伤诱导修复病灶中γ - h2ax分子的计数)证明了定量评价的有效性。

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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Resolution and Discovery

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