Deep Learning Enables Stochastic Optical Reconstruction Microscopy-like Superresolution Image Reconstruction from Conventional Microscopy

Overview

Journal iScience

Publisher Cell Press

Date 2023 Oct 23

PMID 37867953

Authors

Lei Xu

Shichao Kan

Xiying Yu

Ye Liu

Yuxia Fu

Yiqiang Peng

Yanhui Liang

Yigang Cen

Changjun Zhu

Wei Jiang

Affiliations

Soon will be listed here.

Abstract

Despite its remarkable potential for transforming low-resolution images, deep learning faces significant challenges in achieving high-quality superresolution microscopy imaging from wide-field (conventional) microscopy. Here, we present X-Microscopy, a computational tool comprising two deep learning subnets, UR-Net-8 and X-Net, which enables STORM-like superresolution microscopy image reconstruction from wide-field images with input-size flexibility. X-Microscopy was trained using samples of various subcellular structures, including cytoskeletal filaments, dot-like, beehive-like, and nanocluster-like structures, to generate prediction models capable of producing images of comparable quality to STORM-like images. In addition to enabling multicolour superresolution image reconstructions, X-Microscopy also facilitates superresolution image reconstruction from different conventional microscopic systems. The capabilities of X-Microscopy offer promising prospects for making superresolution microscopy accessible to a broader range of users, going beyond the confines of well-equipped laboratories.

Citing Articles

Surpassing the Diffraction Limit in Label-Free Optical Microscopy.

Palounek D, Vala M, Bujak L, Kopal I, Jirikova K, Shaidiuk Y ACS Photonics. 2024; 11(10):3907-3921.

PMID: 39429866 PMC: 11487630. DOI: 10.1021/acsphotonics.4c00745.

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