PT  - JOURNAL ARTICLE
AU  - Martin Hailstone
AU  - Dominic Waithe
AU  - Tamsin J Samuels
AU  - Lu Yang
AU  - Ita Costello
AU  - Yoav Arava
AU  - Elizabeth J Robertson
AU  - Richard M Parton
AU  - Ilan Davis
TI  - CytoCensus: mapping cell identity and division in tissues and organs using machine learning
AID  - 10.1101/137406
DP  - 2019 Jan 01
TA  - bioRxiv
PG  - 137406
4099  - http://biorxiv.org/content/early/2019/08/16/137406.short
4100  - http://biorxiv.org/content/early/2019/08/16/137406.full
AB  - A major challenge in cell and developmental biology is the automated identification and quantitation of cells in complex multilayered tissues. We developed CytoCensus: an easily deployed implementation of supervised machine learning that extends convenient 2D “point- and-click” user training to 3D detection of cells in challenging datasets with ill-defined cell boundaries. In tests on these datasets, CytoCensus outperforms other freely available image analysis software in accuracy and speed of cell detection. We used CytoCensus to count stem cells and their progeny, and to quantify individual cell divisions from time-lapse movies of explanted Drosophila larval brains, comparing wild-type and mutant phenotypes. We further illustrate the general utility and future potential of CytoCensus by analysing the 3D organisation of multiple cell classes in Zebrafish retinal organoids and cell distributions in mouse embryos. CytoCensus opens the possibility of straightforward and robust automated analysis of developmental phenotypes in complex tissues.Summary Hailstone et al. develop CytoCensus, a “point-and-click” supervised machine-learning image analysis software to quantitatively identify defined cell classes and divisions from large multidimensional data sets of complex tissues. They demonstrate its utility in analysing challenging developmental phenotypes in living explanted Drosophila larval brains, mammalian embryos and zebrafish organoids. They further show, in comparative tests, a significant improvement in performance over existing easy-to-use image analysis software.HighlightsCytoCensus: machine learning quantitation of cell types in complex 3D tissuesSingle cell analysis of division rates from movies of living Drosophila brains in 3DDiverse applications in the analysis of developing vertebrate tissues and organoidsOutperforms other image analysis software on challenging, low SNR datasets tested