Unpaired Underwater Image Enhancement Based on CycleGAN

Du, Rong; Li, Weiwei; Chen, Shudong; Li, Congying; Zhang, Yong

doi:10.3390/info13010001

Cited by 11 publications

(5 citation statements)

References 29 publications

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“…We believe that our model is robust; however, as with any AI model, it may be subjected to unintended bias [ 17 , 18 ]. CycleGAN models are good at improving the visual quality of images, but like GANs, in general, they have no guarantees that the details will match a ground truth exactly.…”

Section: Discussionmentioning

confidence: 99%

“…We divided each karyogram image into 23 images, i.e., each karyogram generates 23 pairs, each consisting of a chromosome pair except for chromosomes X and Y, see Figure 1. Additionally, to mitigate the chromosomes' shape and length model bias, we removed chromosomes 13,14,15,16,17,18,19,20,21,22, X, and Y from the training set. This pre-processing step maximizes the shape and length similarity between chromosomes.…”

Section: Data Selectionmentioning

confidence: 99%

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ChromoEnhancer: An Artificial-Intelligence-Based Tool to Enhance Neoplastic Karyograms as an Aid for Effective Analysis

Bokhari

Alhareeri

Aljouie

et al. 2022

Cells

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Cytogenetics laboratory tests are among the most important procedures for the diagnosis of genetic diseases, especially in the area of hematological malignancies. Manual chromosomal karyotyping methods are time consuming and labor intensive and, hence, expensive. Therefore, to alleviate the process of analysis, several attempts have been made to enhance karyograms. The current chromosomal image enhancement is based on classical image processing. This approach has its limitations, one of which is that it has a mandatory application to all chromosomes, where customized application to each chromosome is ideal. Moreover, each chromosome needs a different level of enhancement, depending on whether a given area is from the chromosome itself or it is just an artifact from staining. The analysis of poor-quality karyograms, which is a difficulty faced often in preparations from cancer samples, is time consuming and might result in missing the abnormality or difficulty in reporting the exact breakpoint within the chromosome. We developed ChromoEnhancer, a novel artificial-intelligence-based method to enhance neoplastic karyogram images. The method is based on Generative Adversarial Networks (GANs) with a data-centric approach. GANs are known for the conversion of one image domain to another. We used GANs to convert poor-quality karyograms into good-quality images. Our method of karyogram enhancement led to robust routine cytogenetic analysis and, therefore, to accurate detection of cryptic chromosomal abnormalities. To evaluate ChromoEnahancer, we randomly assigned a subset of the enhanced images and their corresponding original (unenhanced) images to two independent cytogeneticists to measure the karyogram quality and the elapsed time to complete the analysis, using four rating criteria, each scaled from 1 to 5. Furthermore, we compared the enhanced images with our method to the original ones, using quantitative measures (PSNR and SSIM metrics).

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Section: Discussionmentioning

confidence: 99%

Section: Data Selectionmentioning

confidence: 99%

ChromoEnhancer: An Artificial-Intelligence-Based Tool to Enhance Neoplastic Karyograms as an Aid for Effective Analysis

Bokhari

Alhareeri

Aljouie

et al. 2022

Cells

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“…In the context of nuclei segmentation, pix2pix has been used by the authors of nucleAIzer for data augmentation of their training nuclei datasets. Specialized image enhancement models have been since proposed, such as Cycle-CBAM (You et al, 2019) for retinal image enhancement and UW-CycleGAN (Du et al, 2021) for underwater image enhancement, both based on the CycleGAN architecture. Moreover, enhancement of objects of interest has been proposed by the authors of DE-CycleGAN (Gao et al, 2021) to enhance the weak targets for the purpose of accurate vehicle detection.…”

Section: Image To Image Translationmentioning

confidence: 99%

SalienceNet: an unsupervised Image-to-Image translation method for nuclei saliency enhancement in microscopy images

Bouilhol¹

2022

Preprint

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Automatic segmentation of nuclei in low-light microscopy images remains a difficult task, especially for high-throughput experiments where need for automation is strong. Low saliency of nuclei with respect to the background, variability of their intensity together with low signal-to-noise ratio in these images constitute a major challenge for mainstream algorithms of nuclei segmentation. In this work we introduce SalienceNet, an unsupervised deep learning-based method that uses the style transfer properties of cycleGAN to transform low saliency images into high saliency images, thus enabling accurate segmentation by downstream analysis methods, and that without need for any parameter tuning. We have acquired a novel dataset of organoid images with soSPIM, a microscopy technique that enables the acquisition of images in low-light conditions. Our experiments show that SalienceNet increased the saliency of these images up to the desired level. Moreover, we evaluated the impact of SalienceNet on segmentation for both Otsu thresholding and StarDist and have shown that enhancing nuclei with SalienceNet improved segmentation results using Otsu thresholding by 30% and using StarDist by 26% in terms of IOU when compared to segmentation of non-enhanced images. Together these results show that SalienceNet can be used as a common preprocessing step to automate nuclei segmentation pipelines for low-light microscopy images.

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“…An end-to-end underwater image enhancement method based on CycleGAN for an unpaired dataset was proposed by Du et al in 2022. They used URPC2019 and EUVP datasets to train the model, effectively restored the blue-green background, and transformed a blurred underwater degraded image into a clear image [ 31 ]. Their work proves that CycleGAN can effectively enhance underwater images, but because its dataset requires clear underwater images and fuzzy underwater images at the same time, training the dataset is often difficult in practical work; thus, the application of CycleGAN is limited [ 5 ].…”

Section: Introductionmentioning

confidence: 99%

A New Method for Training CycleGAN to Enhance Images of Cold Seeps in the Qiongdongnan Sea

Yang

Gong

et al. 2023

Sensors

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Clear underwater images can help researchers detect cold seeps, gas hydrates, and biological resources. However, the quality of these images suffers from nonuniform lighting, a limited range of visibility, and unwanted signals. CycleGAN has been broadly studied in regard to underwater image enhancement, but it is difficult to apply the model for the further detection of Haima cold seeps in the South China Sea because the model can be difficult to train if the dataset used is not appropriate. In this article, we devise a new method of building a dataset using MSRCR and choose the best images based on the widely used UIQM scheme to build the dataset. The experimental results show that a good CycleGAN could be trained with the dataset using the proposed method. The model has good potential for applications in detecting the Haima cold seeps and can be applied to other cold seeps, such as the cold seeps in the North Sea. We conclude that the method used for building the dataset can be applied to train CycleGAN when enhancing images from cold seeps.

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Unpaired Underwater Image Enhancement Based on CycleGAN

Cited by 11 publications

References 29 publications

ChromoEnhancer: An Artificial-Intelligence-Based Tool to Enhance Neoplastic Karyograms as an Aid for Effective Analysis

ChromoEnhancer: An Artificial-Intelligence-Based Tool to Enhance Neoplastic Karyograms as an Aid for Effective Analysis

SalienceNet: an unsupervised Image-to-Image translation method for nuclei saliency enhancement in microscopy images

A New Method for Training CycleGAN to Enhance Images of Cold Seeps in the Qiongdongnan Sea

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