Learn to segment single cells with deep distance estimator and deep cell detector

Single cell segmentation is a critical and challenging step in cell imaging analysis. Traditional processing methods require time and labor to manually fine-tune parameters and lack parameter transferability between different situations. Recently, deep convolutional neural networks (CNN) treat segme...

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Bibliographic Details
Published in:Computers in biology and medicine 2019-05, Vol.108, p.133-141
Main Authors: Wang, Weikang, Taft, David A., Chen, Yi-Jiun, Zhang, Jingyu, Wallace, Callen T., Xu, Min, Watkins, Simon C., Xing, Jianhua
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Artificial neural networks
Automation
Blurry boundary
Boundaries
Cell count accuracy
Cell Line
Cell Tracking
Classification
Connected cells
Convolutional neural networks
Data analysis
Databases, Factual
Euclidean geometry
Fluorescence
Humans
Image classification
Image contrast
Image detection
Image processing
Image Processing, Computer-Assisted
Image segmentation
Methods
Neural networks
Neural Networks, Computer
Parameters
Phase contrast
Pixels
Sensors
Watershed
Watersheds
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Summary:Single cell segmentation is a critical and challenging step in cell imaging analysis. Traditional processing methods require time and labor to manually fine-tune parameters and lack parameter transferability between different situations. Recently, deep convolutional neural networks (CNN) treat segmentation as a pixel-wise classification problem and have become a general and efficient method for image segmentation. However, cell imaging data often possesses characteristics that adversely affect segmentation accuracy: absence of established training datasets, few pixels on cell boundaries, and ubiquitous blurry features. We developed a strategy that combines strengths of CNN and traditional watershed algorithm. First, we trained a CNN to learn Euclidean distance transform (EDT) of the mask corresponding to the input images (deep distance estimator). Next, we trained a faster R-CNN (Region with CNN) to detect individual cells in the EDT image (deep cell detector). Then, the watershed algorithm performed the final segmentation using the outputs of previous two steps. Tests on a library of fluorescence, phase contrast and differential interference contrast (DIC) images showed that both the combined method and various forms of the pixel-wise classification algorithm achieved similar pixel-wise accuracy. However, the combined method achieved significantly higher cell count accuracy than the pixel-wise classification algorithm did, with the latter performing poorly when separating connected cells, especially those connected by blurry boundaries. This difference is most obvious when applied to noisy images of densely packed cells. Furthermore, both deep distance estimator and deep cell detector converge fast and are easy to train. [Display omitted] •Combines convolutional neural networks and watershed for single cell segmentation.•Combined method achieves significantly improved cell count accuracy.•Allows separation of connected cells with shared blurry boundaries.
ISSN:0010-4825
1879-0534
1879-0534
DOI:10.1016/j.compbiomed.2019.04.006