Abstract
Herein, we implement and access machine learning architectures to ascertain models that differentiate healthy from apoptotic cells using exclusively forward (FSC) and side (SSC) scatter flow cytometry information. To generate training data, colorectal cancer HCT116 cells were subjected to miR-34a treatment and then classified using a conventional Annexin V/propidium iodide (PI)-staining assay. The apoptotic cells were defined as Annexin V-positive cells, which include early and late apoptotic cells, necrotic cells, as well as other dying or dead cells. In addition to fluorescent signal, we collected cell size and granularity information from the FSC and SSC parameters. Both parameters are subdivided into area, height, and width, thus providing a total of six numerical features that informed and trained our models. A collection of logistical regression, random forest, k-nearest neighbor, multilayer perceptron, and support vector machine was trained and tested for classification performance in predicting cell states using only the six aforementioned numerical features. Out of 1046 candidate models, a multilayer perceptron was chosen with 0.91 live precision, 0.93 live recall, 0.92 live f value and 0.97 live area under the ROC curve when applied on standardized data. We discuss and highlight differences in classifier performance and compare the results to the standard practice of forward and side scatter gating, typically performed to select cells based on size and/or complexity. We demonstrate that our model, a ready-to-use module for any flow cytometry-based analysis, can provide automated, reliable, and stain-free classification of healthy and apoptotic cells using exclusively size and granularity information.
Highlights
Since its invention in 1960s, fluorescence-based flow cytometry has become one of the most powerful tools in biomedical research to efficiently and quantitatively analyze information of cellular properties at single-cell level, which range from cell counting and sorting to determining cell characteristics and states[1,2,3]
The processing of the samples commences by selecting cells based on their size and granularity, with a general gating strategy based on the forward scatter (FSC) and side scatter (SSC) values, which are correlated with the size and granularity of the cells, respectively[4,5]
PS is translocated to the outer leaflet of the cell membrane in an ATP-dependent manner to become accessible for signal detection by phagocytic cells[6]
Summary
Since its invention in 1960s, fluorescence-based flow cytometry has become one of the most powerful tools in biomedical research to efficiently and quantitatively analyze information of cellular properties at single-cell level, which range from cell counting and sorting to determining cell characteristics and states[1,2,3]. The training dataset (6828 cells, Supplementary Table 1) contained 3411 live cells and 3417 apoptotic cells.
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