Abstract
We describe a new supervised learning-based template matching approach for segmenting cell nuclei from microscopy images. The method uses examples selected by a user for building a statistical model that captures the texture and shape variations of the nuclear structures from a given dataset to be segmented. Segmentation of subsequent, unlabeled, images is then performed by finding the model instance that best matches (in the normalized cross correlation sense) local neighborhood in the input image. We demonstrate the application of our method to segmenting nuclei from a variety of imaging modalities, and quantitatively compare our results to several other methods. Quantitative results using both simulated and real image data show that, while certain methods may work well for certain imaging modalities, our software is able to obtain high accuracy across several imaging modalities studied. Results also demonstrate that, relative to several existing methods, the template-based method we propose presents increased robustness in the sense of better handling variations in illumination, variations in texture from different imaging modalities, providing more smooth and accurate segmentation borders, as well as handling better cluttered nuclei.
Highlights
Segmenting cell nuclei from microscopy images is an important image processing task necessary for many scientific and clinical applications due to the fundamentally important role of nuclei in cellular processes and diseases
1) Data Acquisition—We demonstrate our system applied to several different cell nuclei datasets: (1) a synthetic dataset BBBC004v1 generated with the SIMCEP simulating platform for fluorescent cell population images [55], [56]; (2) two real cell datasets (U2OS cells and NIH3T3 cells) acquired with fluorescence imaging [57]; (3) and a histopathology dataset obtained using thyroid tissue specimens with several different staining techniques
We described a method for segmenting cell nuclei from several different modalities of images based on supervised learning and template matching
Summary
Segmenting cell nuclei from microscopy images is an important image processing task necessary for many scientific and clinical applications due to the fundamentally important role of nuclei in cellular processes and diseases. Thresholding techniques [17], [18], followed by standard morphological operations, are amongst the simplest and most computationally efficient strategies. These techniques, are inadequate when the data contains strong intensity variations, noise, or when nuclei appear crowded in the field of view [9], [19] being imaged. The watershed method is able to segment touching or overlapping nuclei. Different algorithms for extracting seeds have been proposed. Morphological algorithms (e.g. dilation and erosion) [9] can be used iteratively to overcome inaccuracies in segmentation. Similar ideas using neural networks can be seen in [24]
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