Evaluation of Deep Learning Architectures for Complex Immunofluorescence Nuclear Image Segmentation

Kromp, Florian; Fischer, Lukas; Bozsaky, Eva; Ambros, Inge M.; Dörr, Wolfgang; Beiske, Klaus; Ambros, Peter F.; Hanbury, Allan; Taschner‐Mandl, Sabine

doi:10.1109/tmi.2021.3069558

Cited by 56 publications

(35 citation statements)

References 53 publications

(121 reference statements)

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“…Cell counting and segmentation is a common challenge in high-throughput analysis of optical microscopy images [8, 9, 12, 33, 34]. Both fully- and weakly-supervised DL approaches were shown to be very powerful to assess these tasks on multiple cell lines [7, 25].…”

Section: Resultsmentioning

confidence: 99%

MICRA-Net: MICRoscopy Analysis Neural Network to solve detection, classification, and segmentation from a single simple auxiliary task

Bilodeau¹,

Delmas

Parent

et al. 2021

Preprint

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High throughput quantitative analysis of microscopy images presents a challenge due to the complexity of the image content and the difficulty to retrieve precisely annotated datasets. In this paper we introduce a weakly-supervised MICRoscopy Analysis neural network (MICRA-Net) that can be trained on a simple main classification task using image-level annotations to solve multiple the more complex auxiliary semantic segmentation task and other associated tasks such as detection or enumeration. MICRA-Net relies on the latent information embedded within a trained model to achieve performances similar to state-of-the-art fully-supervised learning. This learnt information is extracted from the network using gradient class activation maps, which are combined to generate detailed feature maps of the biological structures of interest. We demonstrate how MICRA-Net significantly alleviates the Expert annotation process on various microscopy datasets and can be used for high-throughput quantitative analysis of microscopy images.

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Section: Resultsmentioning

confidence: 99%

MICRA-Net: MICRoscopy Analysis Neural Network to solve detection, classification, and segmentation from a single simple auxiliary task

Bilodeau¹,

Delmas

Parent

et al. 2021

Preprint

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“…This Unet extracts cell boundaries that are processed using 3D watershed along with conditional random fields ( a prediction concept which uses contextual information from previous labels) . (Kromp et al, 2019) and the Mask RCNN architecture was found to outperform the UNet based models in the 2D segmentation task. It may be noted that for evaluation (Zaki et al, 2020) use F1-score, while (Kromp et al, 2019) use under/oversegmentation and aggregated Jaccard index.…”

Section: Acknowledgementmentioning

confidence: 96%

Benchmarking of deep learning algorithms for 3D instance segmentation of confocal image datasets

Kar

Petit

Refahi

et al. 2021

Preprint

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Segmenting three dimensional microscopy images is essential for understanding phenomena like morphogenesis, cell division, cellular growth and genetic expression patterns. Recently, deep learning (DL) pipelines have been developed which claim to provide high accuracy segmentation of cellular images and are increasingly considered as the state-of-the-art for image segmentation problems. However, it remains difficult to define their relative performance as the concurrent diversity and lack of uniform evaluation strategies makes it difficult to know how their results compare. In this paper, we first made an inventory of the available DL methods for 3D segmentation. We next implemented and quantitatively compared a number of representative DL pipelines, alongside a highly efficient non-DL method named MARS. The DL methods were trained on a common dataset of 3D cellular confocal microscopy images. Their segmentation accuracies were also tested in the presence of different image artefacts. A new method for segmentation quality evaluation was adopted which isolates segmentation errors due to under/over segmentation. This is complemented with new visualisation strategies that make interactive exploration of segmentation quality possible. Our analysis shows that the DL pipelines have very different levels of accuracy. Two of them show high performance, and offer clear advantages in terms of adaptability to new data.

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“…Nuclei size often varies signi cantly (from a few microns to tens of microns) among different cell types, cultured cells and tissues. Scale makes a signi cant difference in segmentation accuracy [2,15]. Networks trained on a limited dataset without scale variation or image augmentation, may get locked into recognizing only a limited set of nuclear sizes, resulting in over or under segmentation of instances as well as increased false negatives and splits and merges when applied to a test set containing different nuclear sizes.…”

Section: Effects Of Scalementioning

confidence: 99%

“…Additionally, it suffers from individual user bias and lack of reproducibility. Convolutional neural networks (CNNs) have been adapted for nuclei segmentation in wide-eld uorescence images and bright-eld histology images with great success [1][2][3].…”

Section: Introductionmentioning

confidence: 99%

Application of Convolutional Neural Networks Towards Nuclei Segmentation in Localization-based Super-Resolution Fluorescence Microscopy Images

Mela

Liu

2021

Preprint

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Background Automated segmentation of nuclei in microscopic images has been conducted to enhance throughput in pathological diagnostics and biological research. Segmentation accuracy and speed has been significantly enhanced with the advent of convolutional neural networks. A barrier in the broad application of neural networks to nuclei segmentation is the necessity to train the network using a set of application specific images and image labels. Previous works have attempted to create broadly trained networks for universal nuclei segmentation; however, such networks do not work on all imaging modalities, and best results are still commonly found when the network is retrained on user specific data. Stochastic optical reconstruction microscopy (STORM) based super-resolution fluorescence microscopy has opened a new avenue to image nuclear architecture at nanoscale resolutions. Due to the large size and discontinuous features typical of super-resolution images, automatic nuclei segmentation can be difficult. In this study, we apply commonly used networks (Mask R-CNN and UNet architectures) towards the task of segmenting super-resolution images of nuclei. First, we assess whether networks broadly trained on conventional fluorescence microscopy datasets can accurately segment super-resolution images. Then, we compare the resultant segmentations with results obtained using networks trained directly on our super-resolution data. We next attempt to optimize and compare segmentation accuracy using three different neural network architectures. Results Results indicate that super-resolution images are not broadly compatible with neural networks trained on conventional bright-field or fluorescence microscopy images. When the networks were trained on super-resolution data, however, we attained nuclei segmentation accuracies (F1-Score) in excess of 0.8, comparable to past results found when conducting nuclei segmentation on conventional fluorescence microscopy images. Overall, we achieved the best results utilizing the Mask R-CNN architecture. Conclusions We found that convolutional neural networks are powerful tools capable of accurately and quickly segmenting localization-based super-resolution microscopy images of nuclei. While broadly trained and widely applicable segmentation algorithms are desirable for quick use with minimal input, optimal results are still found when the network is both trained and tested on visually similar images. We provide a set of Colab notebooks to disseminate the software into the broad scientific community (https://github.com/YangLiuLab/Super-Resolution-Nuclei-Segmentation).

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Evaluation of Deep Learning Architectures for Complex Immunofluorescence Nuclear Image Segmentation

Cited by 56 publications

References 53 publications

MICRA-Net: MICRoscopy Analysis Neural Network to solve detection, classification, and segmentation from a single simple auxiliary task

MICRA-Net: MICRoscopy Analysis Neural Network to solve detection, classification, and segmentation from a single simple auxiliary task

Benchmarking of deep learning algorithms for 3D instance segmentation of confocal image datasets

Application of Convolutional Neural Networks Towards Nuclei Segmentation in Localization-based Super-Resolution Fluorescence Microscopy Images

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