{"title":"Self-inspired learning for denoising live-cell super-resolution microscopy","authors":"Liying Qu, Shiqun Zhao, Yuanyuan Huang, Xianxin Ye, Kunhao Wang, Yuzhen Liu, Xianming Liu, Heng Mao, Guangwei Hu, Wei Chen, Changliang Guo, Jiaye He, Jiubin Tan, Haoyu Li, Liangyi Chen, Weisong Zhao","doi":"10.1038/s41592-024-02400-9","DOIUrl":null,"url":null,"abstract":"Every collected photon is precious in live-cell super-resolution (SR) microscopy. Here, we describe a data-efficient, deep learning-based denoising solution to improve diverse SR imaging modalities. The method, SN2N, is a Self-inspired Noise2Noise module with self-supervised data generation and self-constrained learning process. SN2N is fully competitive with supervised learning methods and circumvents the need for large training set and clean ground truth, requiring only a single noisy frame for training. We show that SN2N improves photon efficiency by one-to-two orders of magnitude and is compatible with multiple imaging modalities for volumetric, multicolor, time-lapse SR microscopy. We further integrated SN2N into different SR reconstruction algorithms to effectively mitigate image artifacts. We anticipate SN2N will enable improved live-SR imaging and inspire further advances. SN2N, a Self-inspired Noise2Noise module, offers a versatile solution for volumetric time-lapse super-resolution imaging of live cells. SN2N uses self-supervised data generation and self-constrained learning for training with a single noisy frame.","PeriodicalId":18981,"journal":{"name":"Nature Methods","volume":"21 10","pages":"1895-1908"},"PeriodicalIF":36.1000,"publicationDate":"2024-09-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nature Methods","FirstCategoryId":"99","ListUrlMain":"https://www.nature.com/articles/s41592-024-02400-9","RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"BIOCHEMICAL RESEARCH METHODS","Score":null,"Total":0}
引用次数: 0
Abstract
Every collected photon is precious in live-cell super-resolution (SR) microscopy. Here, we describe a data-efficient, deep learning-based denoising solution to improve diverse SR imaging modalities. The method, SN2N, is a Self-inspired Noise2Noise module with self-supervised data generation and self-constrained learning process. SN2N is fully competitive with supervised learning methods and circumvents the need for large training set and clean ground truth, requiring only a single noisy frame for training. We show that SN2N improves photon efficiency by one-to-two orders of magnitude and is compatible with multiple imaging modalities for volumetric, multicolor, time-lapse SR microscopy. We further integrated SN2N into different SR reconstruction algorithms to effectively mitigate image artifacts. We anticipate SN2N will enable improved live-SR imaging and inspire further advances. SN2N, a Self-inspired Noise2Noise module, offers a versatile solution for volumetric time-lapse super-resolution imaging of live cells. SN2N uses self-supervised data generation and self-constrained learning for training with a single noisy frame.
在活细胞超分辨率(SR)显微镜中,每一个收集到的光子都弥足珍贵。在此,我们介绍一种数据高效、基于深度学习的去噪解决方案,以改进各种 SR 成像模式。该方法名为 SN2N,是一种自启发 Noise2Noise 模块,具有自监督数据生成和自约束学习过程。SN2N 与监督学习方法相比完全具有竞争力,而且无需大量训练集和干净的地面实况,只需单个噪声帧进行训练。我们的研究表明,SN2N 可将光子效率提高一到两个数量级,并可与多种成像模式兼容,用于体积、多色、延时 SR 显微镜。我们进一步将 SN2N 集成到不同的 SR 重建算法中,以有效减少图像伪影。我们预计,SN2N 将改善实时 SR 成像,并推动进一步的发展。
期刊介绍:
Nature Methods is a monthly journal that focuses on publishing innovative methods and substantial enhancements to fundamental life sciences research techniques. Geared towards a diverse, interdisciplinary readership of researchers in academia and industry engaged in laboratory work, the journal offers new tools for research and emphasizes the immediate practical significance of the featured work. It publishes primary research papers and reviews recent technical and methodological advancements, with a particular interest in primary methods papers relevant to the biological and biomedical sciences. This includes methods rooted in chemistry with practical applications for studying biological problems.