Prediction of Cellular Identities from Trajectory and Cell Fate
Information
- URL: http://arxiv.org/abs/2401.06182v2
- Date: Sat, 2 Mar 2024 17:59:41 GMT
- Title: Prediction of Cellular Identities from Trajectory and Cell Fate
Information
- Authors: Baiyang Dai, Jiamin Yang, Hari Shroff, Patrick La Riviere
- Abstract summary: We propose an innovative approach to cell identification during early $textitC. elegansgenesis using machine learning.
We employ random forest, embryo, and LSTM models, and tested cell classification accuracy on 3D time-lapse datasets spanning the first 4 hours of embryogenesis.
Our research demonstrates the success of predicting cell identities in time-lapse imaging sequences directly from simple spatial-temporal features.
- Score: 0.40964539027092917
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Determining cell identities in imaging sequences is an important yet
challenging task. The conventional method for cell identification is via cell
tracking, which is complex and can be time-consuming. In this study, we propose
an innovative approach to cell identification during early $\textit{C.
elegans}$ embryogenesis using machine learning. Cell identification during
$\textit{C. elegans}$ embryogenesis would provide insights into neural
development with implications for higher organisms including humans. We
employed random forest, MLP, and LSTM models, and tested cell classification
accuracy on 3D time-lapse confocal datasets spanning the first 4 hours of
embryogenesis. By leveraging a small number of spatial-temporal features of
individual cells, including cell trajectory and cell fate information, our
models achieve an accuracy of over 91%, even with limited data. We also
determine the most important feature contributions and can interpret these
features in the context of biological knowledge. Our research demonstrates the
success of predicting cell identities in time-lapse imaging sequences directly
from simple spatio-temporal features.
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