Abstract
Abstract The analysis of microscopic images from cell cultures plays an important role in the development of drugs. The segmentation of such images is a basic step to extract the viable information on which further evaluation steps are build. Classical image processing pipelines often fail under heterogeneous conditions. In the recent years deep neuronal networks gained attention due to their great potentials in image segmentation. One main pitfall of deep learning is often seen in the amount of labeled data required for training such models. Especially for 3D images the process to generate such data is tedious and time consuming and thus seen as a possible reason for the lack of establishment of deep learning models for 3D data. Efforts have been made to minimize the time needed to create labeled training data or to reduce the amount of labels needed for training. In this paper we present a new semisupervised training method for image segmentation of microscopic cell recordings based on an iterative approach utilizing unlabeled data during training. This method helps to further reduce the amount of labels required to effectively train deep learning models for image segmentation. By labeling less than one percent of the training data, a performance of 90% compared to a full annotation with 342 nuclei can be achieved.
Highlights
Cell cultures can be used to examine the effectiveness and selectivity of an anti-cancer drug without the need to sacrifice animals
A large part of such studies relies on the evaluation of microscopic images, since they offer a wealth of information
In this paper we introduce a new method for semisupervised learning which utilizes iterative training in combination with a new approach to extract labels based on the three class approach used for sparse labeling in [6]
Summary
Cell cultures can be used to examine the effectiveness and selectivity of an anti-cancer drug without the need to sacrifice animals. Since the goal is to minimize the labeling effort, the user annotates only a few objects representative for the data set including their surrounding background. The U-net is used to segment the unlabeled data and a post-processing step consisting of a morphological closing using a 3×3 square structuring element is performed to remove noise and to smooth the boundaries.
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