Abstract
To answer major questions of cell biology, it is often essential to understand the complex phenotypic composition of cellular systems precisely. Modern automated microscopes produce vast amounts of images routinely, making manual analysis nearly impossible. Due to their efficiency, machine learning-based analysis software have become essential tools to perform single-cell-level phenotypic analysis of large imaging datasets. However, an important limitation of such methods is that they do not use the information gained from the cellular micro- and macroenvironment: the algorithmic decision is based solely on the local properties of the cell of interest. Here, we present how various features from the surrounding environment contribute to identifying a cell and how such additional information can improve single-cell-level phenotypic image analysis. The proposed methodology was tested for different sizes of Euclidean and nearest neighbour-based cellular environments both on tissue sections and cell cultures. Our experimental data verify that the surrounding area of a cell largely determines its entity. This effect was found to be especially strong for established tissues, while it was somewhat weaker in the case of cell cultures. Our analysis shows that combining local cellular features with the properties of the cell’s neighbourhood significantly improves the accuracy of machine learning-based phenotyping.
Highlights
Recent improvements in microscopy and computational cell biology have led to an explosion of data volume, often as large as millions of images
Advanced Cell Classifier (ACC) is a graphical image analysis software tool that offers a variety of machine learning methods[17]
Based on strong advice from biologists and pathologists, who definitely highlight the importance of cellular environment, we expected that taking neighbourhood features into account will increase the performance of machine learning
Summary
Recent improvements in microscopy and computational cell biology have led to an explosion of data volume, often as large as millions of images. Single-cell segmentation approaches often prove to be inefficient, for example in the case of tissue section image analysis. CellProfiler Analyst is an extension to CellProfiler and performs supervised learning from extracted features to recognize a single phenotype in individual cell images[13,14].
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