Life sciences require the third dimension with high spatial and temporal resolution

A. Diaspro
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Abstract

A recognized advantage of optical microscopy lies in the fact that allows non-invasive three-dimensional (3D) imaging of live cells at the submicron scale with high specificity [1]. The advent of the visible fluorescent proteins [2] and of a myriad of fluorescent tags pushed fluorescence microscopy to become the most popular imaging tool in cell biology. The confocal and multiphoton versions of fluorescence microscopy reinforce this condition. In general, is a well-known paradigm the given inability of a lens-based optical microscope to discern details that are closer together than half of the wavelength of light. Recently, the viewpoint for improving resolution moved from optical solutions to the side of the fluorescent molecule to be detected. Today, for the most popular imaging mode in optical microscopy, i.e. fluorescence, the diffraction barrier is crumbling and the term “optical nanoscopy”, coined earlier, comes to be a real far field optical microscope available for the scientific community as the ones allowing individual molecule localization at high precision [3, 4]. Here we discuss about architectures, calibrations and applications of targeted and stochastic readout methods using both single and multiphoton excitation with emphasis towards three-dimensional imaging with high spatial and temporal resolution [5–7].
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生命科学需要具有高时空分辨率的第三维度
光学显微镜的一个公认的优势在于,它可以在亚微米尺度上对活细胞进行无创的三维(3D)成像,并且具有高特异性[1]。可见荧光蛋白[2]和无数荧光标签的出现,推动荧光显微镜成为细胞生物学中最流行的成像工具。荧光显微镜的共聚焦和多光子版本加强了这种情况。一般来说,这是一个众所周知的范例,即基于透镜的光学显微镜无法分辨距离比光波长一半更近的细节。最近,提高分辨率的观点从光学溶液转移到要检测的荧光分子的一侧。今天,对于光学显微镜中最流行的成像模式,即荧光,衍射屏障正在瓦解,而早先创造的术语“光学纳米显微镜”,成为科学界可以使用的真正的远场光学显微镜,因为它可以高精度地定位单个分子[3,4]。在这里,我们讨论了使用单光子和多光子激励的靶向和随机读出方法的架构、校准和应用,重点是高时空分辨率的三维成像[5-7]。
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