Debdoot Sheet scite author profile

Optical coherence tomography (OCT) is used for non-invasive diagnosis of diabetic macular edema assessing the retinal layers. In this paper, we propose a new fully convolutional deep architecture, termed ReLayNet, for end-to-end segmentation of retinal layers and fluid masses in eye OCT scans. ReLayNet uses a contracting path of convolutional blocks (encoders) to learn a hierarchy of contextual features, followed by an expansive path of convolutional blocks (decoders) for semantic segmentation. ReLayNet is trained to optimize a joint loss function comprising of weighted logistic regression and Dice overlap loss. The framework is validated on a publicly available benchmark dataset with comparisons against five state-of-the-art segmentation methods including two deep learning based approaches to substantiate its effectiveness.

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CHAOS Challenge - combined (CT-MR) healthy abdominal organ segmentation

Kavur

Gezer

Barış

et al. 2021

Medical Image Analysis

491

176

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Brightness preserving dynamic fuzzy histogram equalization

Sheet

Garud

Suveer

et al. 2010

IEEE Trans. Consumer Electron.

348

176

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IDRiD: Diabetic Retinopathy – Segmentation and Grading Challenge

Porwal

Pachade

Kokare³

et al. 2020

Medical Image Analysis

233

113

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challenge. This paper outlines the challenge, its organization, the dataset used, evaluation methods and results of top performing participating solutions. We observe that the top performing approaches utilize a blend of clinical information, data augmentation, and the ensemble of models. These findings have the potential to enable new developments in retinal image analysis and image-based DR screening in particular.

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Error Corrective Boosting for Learning Fully Convolutional Networks with Limited Data

Roy

Conjeti

Sheet

et al. 2017

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Abstract. Training deep fully convolutional neural networks (F-CNNs) for semantic image segmentation requires access to abundant labeled data. While large datasets of unlabeled image data are available in medical applications, access to manually labeled data is very limited. We propose to automatically create auxiliary labels on initially unlabeled data with existing tools and to use them for pre-training. For the subsequent fine-tuning of the network with manually labeled data, we introduce error corrective boosting (ECB), which emphasizes parameter updates on classes with lower accuracy. Furthermore, we introduce SkipDeconv-Net (SD-Net), a new F-CNN architecture for brain segmentation that combines skip connections with the unpooling strategy for upsampling. The SD-Net addresses challenges of severe class imbalance and errors along boundaries. With application to whole-brain MRI T1 scan segmentation, we generate auxiliary labels on a large dataset with FreeSurfer and finetune on two datasets with manual annotations. Our results show that the inclusion of auxiliary labels and ECB yields significant improvements. SD-Net segments a 3D scan in 7 secs in comparison to 30 hours for the closest multi-atlas segmentation method, while reaching similar performance. It also outperforms the latest state-of-the-art F-CNN models.

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Debdoot Sheet

ReLayNet: retinal layer and fluid segmentation of macular optical coherence tomography using fully convolutional networks

CHAOS Challenge - combined (CT-MR) healthy abdominal organ segmentation

Brightness preserving dynamic fuzzy histogram equalization

IDRiD: Diabetic Retinopathy – Segmentation and Grading Challenge

Error Corrective Boosting for Learning Fully Convolutional Networks with Limited Data

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