Tetra-color superresolution microscopy based on excitation spectral demixing
Wanyan Wu, Shihang Luo, Chunyan Fan, Tianjie Yang, Shuwen Zhang, Wenxiang Meng, Tao Xu, Wei Ji & Lusheng Gu
Abstract
Multicolor imaging allows protein colocalizations and organelle interactions to be studied in biological research, which is especially important for single-molecule localization microscopy (SMLM). Here, we propose a multicolor method called excitation-resolved stochastic optical reconstruction microscopy (ExR-STORM). The method, which is based on the excitation spectrum of fluorescent dyes, successfully separated four spectrally very close far-red organic fluorophores utilizing three excitation lasers with cross-talk of less than 3%. Dyes that are only 5 nm apart in the emission spectrum were resolved, resulting in negligible chromatic aberrations. This method was extended to three-dimensional (3D) imaging by combining the astigmatic method, providing a powerful tool for resolving 3D morphologies at the nanoscale.
最新重要论文
Tetra-color superresolution microscopy based on excitation spectral demixing, Light-Sci Appl, 2 Jan 2023
Light: Science & Applications, 2 January, 2023, DOI:https://doi.org/10.1038/s41377-022-01054-6
Tetra-color superresolution microscopy based on excitation spectral demixing
Wanyan Wu, Shihang Luo, Chunyan Fan, Tianjie Yang, Shuwen Zhang, Wenxiang Meng, Tao Xu, Wei Ji & Lusheng Gu
Abstract
Multicolor imaging allows protein colocalizations and organelle interactions to be studied in biological research, which is especially important for single-molecule localization microscopy (SMLM). Here, we propose a multicolor method called excitation-resolved stochastic optical reconstruction microscopy (ExR-STORM). The method, which is based on the excitation spectrum of fluorescent dyes, successfully separated four spectrally very close far-red organic fluorophores utilizing three excitation lasers with cross-talk of less than 3%. Dyes that are only 5 nm apart in the emission spectrum were resolved, resulting in negligible chromatic aberrations. This method was extended to three-dimensional (3D) imaging by combining the astigmatic method, providing a powerful tool for resolving 3D morphologies at the nanoscale.
文章链接:https://www.nature.com/articles/s41377-022-01054-6
相关报道:http://www.ibp.cas.cn/kyjz/zxdt/202301/t20230113_6599081.html