Three-dimensional Residual Channel Attention Networks Denoise and Sharpen Fluorescence Microscopy Image Volumes

Overview

Journal Nat Methods

Specialties Biomedical Engineering
Pathology

Date 2021 Jun 1

PMID 34059829

Citations 52

Authors

Jiji Chen

Hideki Sasaki

Hoyin Lai

Yijun Su

Jiamin Liu

Yicong Wu

Alexander Zhovmer

Christian A Combs

Ivan Rey-Suarez

Hung-Yu Chang

Chi Chou Huang

Xuesong Li

Min Guo

Srineil Nizambad

Arpita Upadhyaya

Shih-Jong J Lee

Luciano A G Lucas

Hari Shroff

Affiliations

Soon will be listed here.

Abstract

We demonstrate residual channel attention networks (RCAN) for the restoration and enhancement of volumetric time-lapse (four-dimensional) fluorescence microscopy data. First we modify RCAN to handle image volumes, showing that our network enables denoising competitive with three other state-of-the-art neural networks. We use RCAN to restore noisy four-dimensional super-resolution data, enabling image capture of over tens of thousands of images (thousands of volumes) without apparent photobleaching. Second, using simulations we show that RCAN enables resolution enhancement equivalent to, or better than, other networks. Third, we exploit RCAN for denoising and resolution improvement in confocal microscopy, enabling ~2.5-fold lateral resolution enhancement using stimulated emission depletion microscopy ground truth. Fourth, we develop methods to improve spatial resolution in structured illumination microscopy using expansion microscopy data as ground truth, achieving improvements of ~1.9-fold laterally and ~3.6-fold axially. Finally, we characterize the limits of denoising and resolution enhancement, suggesting practical benchmarks for evaluation and further enhancement of network performance.

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