Denoising of stimulated Raman scattering microscopy images via deep learning

Manifold, Bryce; Thomas, Elena C.; Francis, Andrew T.; Hill, Andrew H.; Fu, Dan

doi:10.1364/boe.10.003860

Cited by 96 publications

(63 citation statements)

References 42 publications

(36 reference statements)

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“…In recent years, deep learning receives much attention in many research fields including optical design [1,2] and optical imaging [3]. In previous works, deep learning has been extensively applied for many optical imaging problems including phase retrieval [4][5][6][7], microscopic image enhancement [8][9], scattering imaging [10][11], holography [12][13][14][15][16][17][18], single-pixel imaging [19,20], super-resolution [21][22][23][24], Fourier ptychography [25][26][27], optical interferometry [28,29], wavefront sensing [30,31], and optical fiber communications [32].…”

Section: Introductionmentioning

confidence: 99%

Does deep learning always outperform simple linear regression in optical imaging?

et al. 2020

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Deep learning has been extensively applied in many optical imaging problems in recent years. Despite the success, the limitations and drawbacks of deep learning in optical imaging have been seldom investigated. In this work, we show that conventional linear-regression-based methods can outperform the previously proposed deep learning approaches for two black-box optical imaging problems in some extent. Deep learning demonstrates its weakness especially when the number of training samples is small. The advantages and disadvantages of linear-regression-based methods and deep learning are analyzed and compared. Since many optical systems are essentially linear, a deep learning network containing many nonlinearity functions sometimes may not be the most suitable option.

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Section: Introductionmentioning

confidence: 99%

Does deep learning always outperform simple linear regression in optical imaging?

et al. 2020

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“…Deep learning can deeply explore the cellular structure and morphological information in bright‐field images . Some improved label‐free cell Raman scattering imaging techniques are used to study the cell chemical components, such as stimulated Raman scattering, surface enhanced Raman scattering and coherent antistokes Raman scattering, deep learning techniques have emerged in these studies as high‐performance and powerful analytical tools . Deep learning is also applied to other advanced label‐free cell imaging technologies, such as holographic microscopy , time stretch quantitative phase imaging , phase contrast microscopy , and hyperspectral imaging .…”

Section: Applications Of Deep Learning In Single‐cell Optical Image Smentioning

confidence: 99%

Deep Learning‐Based Single‐Cell Optical Image Studies

Sun

Tárnok

2020

Cytometry Pt A

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Optical imaging technology that has the advantages of high sensitivity and cost‐effectiveness greatly promotes the progress of nondestructive single‐cell studies. Complex cellular image analysis tasks such as three‐dimensional reconstruction call for machine‐learning technology in cell optical image research. With the rapid developments of high‐throughput imaging flow cytometry, big data cell optical images are always obtained that may require machine learning for data analysis. In recent years, deep learning has been prevalent in the field of machine learning for large‐scale image processing and analysis, which brings a new dawn for single‐cell optical image studies with an explosive growth of data availability. Popular deep learning techniques offer new ideas for multimodal and multitask single‐cell optical image research. This article provides an overview of the basic knowledge of deep learning and its applications in single‐cell optical image studies. We explore the feasibility of applying deep learning techniques to single‐cell optical image analysis, where popular techniques such as transfer learning, multimodal learning, multitask learning, and end‐to‐end learning have been reviewed. Image preprocessing and deep learning model training methods are then summarized. Applications based on deep learning techniques in the field of single‐cell optical image studies are reviewed, which include image segmentation, super‐resolution image reconstruction, cell tracking, cell counting, cross‐modal image reconstruction, and design and control of cell imaging systems. In addition, deep learning in popular single‐cell optical imaging techniques such as label‐free cell optical imaging, high‐content screening, and high‐throughput optical imaging cytometry are also mentioned. Finally, the perspectives of deep learning technology for single‐cell optical image analysis are discussed. © 2020 International Society for Advancement of Cytometry

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“…Devalla et al proposed a deep convolutional code-decode network for image denoising [23]; Bepler et al use a deeper network structure and residual learning algorithm to improve the denoising performance [24]. Manifold et al proved that neural networks can also learn to recognise self-similarity between images [25]. Inspired by work of Ledig et al [26], we used a generative adversarial network to denoise the original images.…”

Section: Introductionmentioning

confidence: 99%

Photon Scattering Signal Amplification in Gold-Viral Particle Ligation Towards Fast Infection Screening

et al. 2021

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The polarization states of scattered photons can be used to map or image the anisotropic features of a nanostructure. However, the scattering strength depends heavily on the refractivity contrast in the near field under measurement, which limits the imaging sensitivity for viral particles which have little refractivity contrast with their nano-ambientes. In this paper, we show the photon scattering signal strength can be magnified by introducing a more abrupt change of refractivity at the virus particle using antibody-conjugated gold nanoparticles (AuNPs), allowing the presence of such viruses to be detected. Using two different deep learning methods to minimize scattering noise, the photon states scattering signal of a AuNPs ligated virus is enhanced significantly compared to that of a bare virus particle. This is confirmed by Finite Difference Time Domain (FDTD) numerical simulations. The sensitivity of the polarization state scattering spectra from a virus-gold particle doublet is 5.4 times higher than that of a conventional microscope image.

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Denoising of stimulated Raman scattering microscopy images via deep learning

Cited by 96 publications

References 42 publications

Does deep learning always outperform simple linear regression in optical imaging?

Does deep learning always outperform simple linear regression in optical imaging?

Deep Learning‐Based Single‐Cell Optical Image Studies

Photon Scattering Signal Amplification in Gold-Viral Particle Ligation Towards Fast Infection Screening

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