Segmenting and tracking cell instances with cosine embeddings and recurrent hourglass networks. Payer, C., Štern, D., Feiner, M., Bischof, H., & Urschler, M. Medical Image Analysis, 57:106-119, 10, 2019. ![Segmenting and tracking cell instances with cosine embeddings and recurrent hourglass networks [link]](https://bibbase.org/img/filetypes/link.svg "link")
Website doi abstract bibtex Differently to semantic segmentation, instance segmentation assigns unique labels to each individual instance of the same object class. In this work, we propose a novel recurrent fully convolutional network architecture for tracking such instance segmentations over time, which is highly relevant, e.g., in biomedical applications involving cell growth and migration. Our network architecture incorporates convolutional gated recurrent units (ConvGRU) into a stacked hourglass network to utilize temporal information, e.g., from microscopy videos. Moreover, we train our network with a novel embedding loss based on cosine similarities, such that the network predicts unique embeddings for every instance throughout videos, even in the presence of dynamic structural changes due to mitosis of cells. To create the final tracked instance segmentations, the pixel-wise embeddings are clustered among subsequent video frames by using the mean shift algorithm. After showing the performance of the instance segmentation on a static in-house dataset of muscle fibers from H&E-stained microscopy images, we also evaluate our proposed recurrent stacked hourglass network regarding instance segmentation and tracking performance on six datasets from the ISBI celltracking challenge, where it delivers state-of-the-art results.
@article{
title = {Segmenting and tracking cell instances with cosine embeddings and recurrent hourglass networks},
type = {article},
year = {2019},
keywords = {Cell,Embeddings,Instances,Recurrent,Segmentation,Tracking,Video},
pages = {106-119},
volume = {57},
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month = {10},
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abstract = {Differently to semantic segmentation, instance segmentation assigns unique labels to each individual instance of the same object class. In this work, we propose a novel recurrent fully convolutional network architecture for tracking such instance segmentations over time, which is highly relevant, e.g., in biomedical applications involving cell growth and migration. Our network architecture incorporates convolutional gated recurrent units (ConvGRU) into a stacked hourglass network to utilize temporal information, e.g., from microscopy videos. Moreover, we train our network with a novel embedding loss based on cosine similarities, such that the network predicts unique embeddings for every instance throughout videos, even in the presence of dynamic structural changes due to mitosis of cells. To create the final tracked instance segmentations, the pixel-wise embeddings are clustered among subsequent video frames by using the mean shift algorithm. After showing the performance of the instance segmentation on a static in-house dataset of muscle fibers from H&E-stained microscopy images, we also evaluate our proposed recurrent stacked hourglass network regarding instance segmentation and tracking performance on six datasets from the ISBI celltracking challenge, where it delivers state-of-the-art results.},
bibtype = {article},
author = {Payer, Christian and Štern, Darko and Feiner, Marlies and Bischof, Horst and Urschler, Martin},
doi = {10.1016/j.media.2019.06.015},
journal = {Medical Image Analysis}
}
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