增强的光子收集使活系统的四维荧光纳米oscopy 成为可能。

Enhanced photon collection enables four dimensional fluorescence nanoscopy of living systems.

机构信息

Department of Applied Physics and Science for Life Laboratory, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden.

Department of Cell and Molecular Biology, Karolinska Institutet, 17176, Stockholm, Sweden.

出版信息

Nat Commun. 2018 Aug 16;9(1):3281. doi: 10.1038/s41467-018-05799-w.

DOI:10.1038/s41467-018-05799-w

PMID:30115928

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6095837/

Abstract

The theoretically unlimited spatial resolution of fluorescence nanoscopy often comes at the expense of time, contrast and increased dose of energy for recording. Here, we developed MoNaLISA, for Molecular Nanoscale Live Imaging with Sectioning Ability, a nanoscope capable of imaging structures at a scale of 45-65 nm within the entire cell volume at low light intensities (W-kW cm). Our approach, based on reversibly switchable fluorescent proteins, features three distinctly modulated illumination patterns crafted and combined to gain fluorescence ON-OFF switching cycles and image contrast. By maximizing the detected photon flux, MoNaLISA enables prolonged (40-50 frames) and large (50 × 50 µm) recordings at 0.3-1.3 Hz with enhanced optical sectioning ability. We demonstrate the general use of our approach by 4D imaging of organelles and fine structures in epithelial human cells, colonies of mouse embryonic stem cells, brain cells, and organotypic tissues.

摘要

荧光纳米显微镜在理论上具有无限的空间分辨率，但通常需要牺牲时间、对比度和增加记录的能量。在这里，我们开发了 MoNaLISA，即具有切片能力的分子纳米尺度活体成像，这是一种能够在低光强下（W-kW cm）在整个细胞体积内以 45-65nm 的尺度成像结构的纳米显微镜。我们的方法基于可还原开关的荧光蛋白，具有三种明显调制的照明模式，这些模式被精心设计并组合在一起，以获得荧光的 ON-OFF 切换循环和图像对比度。通过最大化检测到的光子通量，MoNaLISA 能够以 0.3-1.3Hz 的速度进行长达 40-50 帧和大尺寸（50×50µm）的记录，并具有增强的光学切片能力。我们通过对上皮人细胞、小鼠胚胎干细胞集落、脑细胞和器官型组织中的细胞器和精细结构进行 4D 成像，证明了我们方法的广泛适用性。

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增强的光子收集使活系统的四维荧光纳米oscopy 成为可能。

Enhanced photon collection enables four dimensional fluorescence nanoscopy of living systems.

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