Václav Uher scite author profile

To stimulate progress in automating the reconstruction of neural circuits, we organized the first international challenge on 2D segmentation of electron microscopic (EM) images of the brain. Participants submitted boundary maps predicted for a test set of images, and were scored based on their agreement with a consensus of human expert annotations. The winning team had no prior experience with EM images, and employed a convolutional network. This “deep learning” approach has since become accepted as a standard for segmentation of EM images. The challenge has continued to accept submissions, and the best so far has resulted from cooperation between two teams. The challenge has probably saturated, as algorithms cannot progress beyond limits set by ambiguities inherent in 2D scoring and the size of the test dataset. Retrospective evaluation of the challenge scoring system reveals that it was not sufficiently robust to variations in the widths of neurite borders. We propose a solution to this problem, which should be useful for a future 3D segmentation challenge.

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Image processing based automatic diagnosis of glaucoma using wavelet features of segmented optic disc from fundus image

Singh

Dutta

Parthasarathi

et al. 2016

Computer Methods and Programs in Biomedicine

182

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Optimized High Resolution 3D Dense-U-Net Network for Brain and Spine Segmentation

et al. 2019

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The 3D image segmentation is the process of partitioning a digital 3D volumes into multiple segments. This paper presents a fully automatic method for high resolution 3D volumetric segmentation of medical image data using modern supervised deep learning approach. We introduce 3D Dense-U-Net neural network architecture implementing densely connected layers. It has been optimized for graphic process unit accelerated high resolution image processing on currently available hardware (Nvidia GTX 1080ti). The method has been evaluated on MRI brain 3D volumetric dataset and CT thoracic scan dataset for spine segmentation. In contrast with many previous methods, our approach is capable of precise segmentation of the input image data in the original resolution, without any pre-processing of the input image. It can process image data in 3D and has achieved accuracy of 99.72% on MRI brain dataset, which outperformed results achieved by human expert. On lumbar and thoracic vertebrae CT dataset it has achieved the accuracy of 99.80%. The architecture proposed in this paper can also be easily applied to any task already using U-Net network as a segmentation algorithm to enhance its results. Complete source code was released online under open-source license.

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Superresolution of MRI brain images using unbalanced 3D Dense-U-Net network

Kolarik

Bürget

Uher

et al. 2019

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Feature Optimization for Run Time Analysis of Malware in Windows Operating System using Machine Learning Approach

Irshad

Maurya

Dutta

et al. 2019

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Václav Uher

Crowdsourcing the creation of image segmentation algorithms for connectomics

Image processing based automatic diagnosis of glaucoma using wavelet features of segmented optic disc from fundus image

Optimized High Resolution 3D Dense-U-Net Network for Brain and Spine Segmentation

Superresolution of MRI brain images using unbalanced 3D Dense-U-Net network

Feature Optimization for Run Time Analysis of Malware in Windows Operating System using Machine Learning Approach

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