Min Zhu, Luhao Zhang, Luhong Jin, Yunyue Chen, Haixu Yang, Baohua Ji, Yingke Xu
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引用次数: 0
Abstract
DNA-based point accumulation in nanoscale topography (DNA-PAINT) is a well-established technique for single-molecule localization microscopy (SMLM), enabling resolution of up to a few nanometers. Traditionally, DNA-PAINT involves the utilization of tens of thousands of single-molecule fluorescent images to generate a single super-resolution image. This process can be time-consuming, which makes it unfeasible for many researchers. Here, we propose a simplified DNA-PAINT labeling method and a deep learning-enabled fast DNA-PAINT imaging strategy for subcellular structures, such as microtubules. By employing our method, super-resolution reconstruction can be achieved with only one-tenth of the raw data previously needed, along with the option of acquiring the widefield image. As a result, DNA-PAINT imaging is significantly accelerated, making it more accessible to a wider range of biological researchers.
基于 DNA 的纳米级地形图点累积(DNA-PAINT)是一种成熟的单分子定位显微镜(SMLM)技术,可实现高达几纳米的分辨率。传统上,DNA-PAINT 需要利用数以万计的单分子荧光图像来生成一张超分辨率图像。这一过程非常耗时,因此对许多研究人员来说并不可行。在这里,我们针对微管等亚细胞结构提出了一种简化的DNA-PAINT标记方法和一种深度学习支持的快速DNA-PAINT成像策略。采用我们的方法,只需以前十分之一的原始数据就能实现超分辨率重建,同时还能选择获取宽场图像。因此,DNA-PAINT 成像的速度大大加快,更多的生物研究人员可以使用这种方法。
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