Optical nanoscopy of a living cell

Optics & Photonics - NanoScience + Engineering Pub Date : 2014-11-19 DOI:10.1117/12.2062581

B. Ahluwalia, D. Wolfson, Frank Y. S. Chuang, T. Huser

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Abstract

Optical nanoscopy allows to study biological and functional processes of sub-cellular organelles. In structured illumination microscopy (SIM) the sample is illuminated with a grid-like interference pattern to encode higher spatial frequency information into observable Moiré patterns. By acquiring multiple images and a computation trick a superresolved image is obtained. SIM provides resolution enhancement of 2X in each axis as compared to conventional microscopes. For a visible light, SIM provides an optical resolution of 100 nm. The challenges associated with optical nanoscopy of a living cell are photo-toxicity, special dye requirements and artifacts due to cell movement. SIM works with conventional dyes and is a wide-field technique making it suitable for imaging living cells. In this work, we will discuss the opportunities and challenges of imaging living cells using SIM. Two applications of optical nanoscopy of living cells will be discussed; a) imaging of mitochondria in a keratinocyte cell and Optical microscopy based on fluorescence has emerged as a vital tool in modern bio-medical imaging and diagnosis. Super-resolution bio-imaging allows gathering information from sub-cellular organelles. In structured illumination microscopy (SIM) the sample is illuminated with a grid-like interference patterns to encode higher spatial frequencies information into observable images (Moiré fringes). A super-resolved image is then decoded using computational trick. In this work, we used SIM to acquired super-resolved optical images of mitochondria from a live keratinocyte cell (see Fig 1). SIM provides resolution enhancement of 2X in each axis and contrast enhancement of 8X on a projected image. Time-lapsed imaging was used to study the dynamics of mitochondria in a live cell.

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活细胞的光学纳米显微镜

光学纳米显微镜可以研究亚细胞细胞器的生物学和功能过程。在结构照明显微镜(SIM)中，样品被类似网格的干涉图案照亮，从而将更高的空间频率信息编码成可观察的莫尔条纹。通过获取多幅图像和一种计算技巧，得到一幅超分辨图像。与传统显微镜相比，SIM在每个轴上提供2X的分辨率增强。对于可见光，SIM提供了100纳米的光学分辨率。与活细胞的光学纳米显微镜相关的挑战是光毒性，特殊染料要求和由于细胞运动而产生的伪影。SIM与传统染料一起工作，是一种适用于活细胞成像的宽领域技术。在这项工作中，我们将讨论使用SIM成像活细胞的机遇和挑战。本文将讨论光学纳米技术在活细胞中的两种应用;a)角质形成细胞线粒体成像和基于荧光的光学显微镜已经成为现代生物医学成像和诊断的重要工具。超分辨率生物成像允许从亚细胞细胞器收集信息。在结构照明显微镜(SIM)中，样品被网格状的干涉图案照亮，以编码更高的空间频率信息到可观察的图像中(莫尔条纹)。然后使用计算技巧对超分辨率图像进行解码。在这项工作中，我们使用SIM从活的角质形成细胞中获取线粒体的超分辨率光学图像(见图1)。SIM在每个轴上提供2X的分辨率增强，在投影图像上提供8X的对比度增强。延时成像用于研究活细胞中线粒体的动力学。

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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Optics & Photonics - NanoScience + Engineering

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