Scientific Basis for the Incorporation of (Not So) New Devices by the Brazilian Public Health System

Generalized nucleus segmentation techniques can contribute greatly to reducing the time to develop and validate visual biomarkers for new digital pathology datasets. We summarize the results of MoNuSeg 2018 Challenge whose objective was to develop generalizable nuclei segmentation techniques in digital pathology. The challenge was an official satellite event of the MICCAI 2018 conference in which 32 teams with more than 80 participants from geographically diverse institutes participated. Contestants were given a training set with 30 images from seven organs with annotations of 21,623 individual nuclei. A test dataset with 14 images taken from seven organs, including two organs that did not appear in the training set was released without annotations. Entries were evaluated based on average aggregated Jaccard index (AJI) on the test set to prioritize accurate instance segmentation as opposed to mere semantic segmentation. More than half the teams that completed the challenge outperformed a previous baseline [1]. Among the trends observed that contributed to increased accuracy were the use of color normalization as well as heavy data augmentation. Additionally, fully convolutional networks inspired by variants of U-Net [2], FCN [3], and Mask- RCNN [4] were popularly used, typically based on ResNet [5] or VGG [6] base architectures. Watershed segmentation on predicted semantic segmentation maps was a popular post-processing strategy. Several of the top techniques compared favorably to an individual human annotator and can be used with confidence for nuclear morphometrics.

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Automated detection and classification of thyroid nodules in ultrasound images using clinical-knowledge-guided convolutional neural networks

Liu

Guo

Lian

et al. 2019

Medical Image Analysis

145

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Interleaved 3D‐CNNs for joint segmentation of small‐volume structures in head and neck CT images

et al. 2018

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Purpose Accurate 3D image segmentation is a crucial step in radiation therapy planning of head and neck tumors. These segmentation results are currently obtained by manual outlining of tissues, which is a tedious and time-consuming procedure. Automatic segmentation provides an alternative solution, which, however, is often difficult for small tissues (i.e., chiasm and optic nerves in head and neck CT images) because of their small volumes and highly diverse appearance/shape information. In this work, we propose to interleave multiple 3D Convolutional Neural Networks (3D-CNNs) to attain automatic segmentation of small tissues in head and neck CT images. Method A 3D-CNN was designed to segment each structure of interest. To make full use of the image appearance information, multi-scale patches are extracted to describe the center voxel under consideration and then input to the CNN architecture. Next, as neighboring tissues are often highly related in the physiological and anatomical perspectives, we interleave the CNNs designated for the individual tissues. In this way, the tentative segmentation result of a specific tissue can contribute to refine the segmentations of other neighboring tissues. Finally, as more CNNs are interleaved and cascaded, a complex network of CNNs can be derived, such that all tissues can be jointly segmented and iteratively refined. Result Our method was validated on a set of 48 CT images, obtained from the Medical Image Computing and Computer Assisted Intervention (MICCAI) Challenge 2015. The Dice coefficient (DC) and the 95% Hausdorff Distance (95HD) are computed to measure the accuracy of the segmentation results. The proposed method achieves higher segmentation accuracy (with the average DC: 0.58±0.17 for optic chiasm, and 0.71±0.08 for optic nerve; 95HD: 2.81±1.56 mm for optic chiasm, and 2.23±0.90 mm for optic nerve) than the MICCAI challenge winner (with the average DC: 0.38 for optic chiasm, and 0.68 for optic nerve; 95HD: 3.48 for optic chiasm, and 2.48 for optic nerve). Conclusion An accurate and automatic segmentation method has been proposed for small tissues in head and neck CT images, which is important for the planning of radiotherapy.

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A Novel Image Classification Method with CNN-XGBoost Model

Ren

Guo

et al. 2017

102

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Regression Convolutional Neural Network for Automated Pediatric Bone Age Assessment From Hand Radiograph

Ren

Yang

et al. 2019

IEEE J. Biomed. Health Inform.

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Segmentation and Classification in Digital Pathology for Glioma Research: Challenges and Deep Learning Approaches

et al. 2020

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Can pretreatment 18F-FDG PET tumor texture features predict the outcomes of osteosarcoma treated by neoadjuvant chemotherapy?

et al. 2019

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Task Decomposition and Synchronization for Semantic Biomedical Image Segmentation

Ren

Ahmad

Zhang

et al. 2020

IEEE Trans. on Image Process.

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Xuhua Ren

A Multi-Organ Nucleus Segmentation Challenge

Automated detection and classification of thyroid nodules in ultrasound images using clinical-knowledge-guided convolutional neural networks

Interleaved 3D‐CNNs for joint segmentation of small‐volume structures in head and neck CT images

A Novel Image Classification Method with CNN-XGBoost Model

Regression Convolutional Neural Network for Automated Pediatric Bone Age Assessment From Hand Radiograph

Segmentation and Classification in Digital Pathology for Glioma Research: Challenges and Deep Learning Approaches

Can pretreatment 18F-FDG PET tumor texture features predict the outcomes of osteosarcoma treated by neoadjuvant chemotherapy?

Task Decomposition and Synchronization for Semantic Biomedical Image Segmentation

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