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FindFoci: A Focus Detection Algorithm with Automated Parameter Training That Closely Matches Human Assignments, Reduces Human Inconsistencies and Increases Speed of Analysis

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  • Alex D Herbert
  • Antony M Carr
  • Eva Hoffmann

Abstract

Accurate and reproducible quantification of the accumulation of proteins into foci in cells is essential for data interpretation and for biological inferences. To improve reproducibility, much emphasis has been placed on the preparation of samples, but less attention has been given to reporting and standardizing the quantification of foci. The current standard to quantitate foci in open-source software is to manually determine a range of parameters based on the outcome of one or a few representative images and then apply the parameter combination to the analysis of a larger dataset. Here, we demonstrate the power and utility of using machine learning to train a new algorithm (FindFoci) to determine optimal parameters. FindFoci closely matches human assignments and allows rapid automated exploration of parameter space. Thus, individuals can train the algorithm to mirror their own assignments and then automate focus counting using the same parameters across a large number of images. Using the training algorithm to match human assignments of foci, we demonstrate that applying an optimal parameter combination from a single image is not broadly applicable to analysis of other images scored by the same experimenter or by other experimenters. Our analysis thus reveals wide variation in human assignment of foci and their quantification. To overcome this, we developed training on multiple images, which reduces the inconsistency of using a single or a few images to set parameters for focus detection. FindFoci is provided as an open-source plugin for ImageJ.

Suggested Citation

  • Alex D Herbert & Antony M Carr & Eva Hoffmann, 2014. "FindFoci: A Focus Detection Algorithm with Automated Parameter Training That Closely Matches Human Assignments, Reduces Human Inconsistencies and Increases Speed of Analysis," PLOS ONE, Public Library of Science, vol. 9(12), pages 1-33, December.
    • Handle: RePEc:plo:pone00:0114749
    DOI: 10.1371/journal.pone.0114749
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    1. William S Sanders & C Ian Johnston & Susan M Bridges & Shane C Burgess & Kenneth O Willeford, 2011. "Prediction of Cell Penetrating Peptides by Support Vector Machines," PLOS Computational Biology, Public Library of Science, vol. 7(7), pages 1-12, July.
    2. Moritz Helmstaedter & Kevin L. Briggman & Srinivas C. Turaga & Viren Jain & H. Sebastian Seung & Winfried Denk, 2013. "Connectomic reconstruction of the inner plexiform layer in the mouse retina," Nature, Nature, vol. 500(7461), pages 168-174, August.
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    1. Tim Hohmann & Jacqueline Kessler & Dirk Vordermark & Faramarz Dehghani, 2020. "Evaluation of machine learning models for automatic detection of DNA double strand breaks after irradiation using a γH2AX foci assay," PLOS ONE, Public Library of Science, vol. 15(2), pages 1-15, February.

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