Stathis Megas, Daniel G. Chen, Krzysztof Polanski, Moshe Eliasof, Carola-Bibiane Schonlieb, Sarah A. Teichmann
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Celcomen: spatial causal disentanglement for single-cell and tissue perturbation modeling
Celcomen leverages a mathematical causality framework to disentangle intra-
and inter- cellular gene regulation programs in spatial transcriptomics and
single-cell data through a generative graph neural network. It can learn
gene-gene interactions, as well as generate post-perturbation counterfactual
spatial transcriptomics, thereby offering access to experimentally inaccessible
samples. We validated its disentanglement, identifiability, and counterfactual
prediction capabilities through simulations and in clinically relevant human
glioblastoma, human fetal spleen, and mouse lung cancer samples. Celcomen
provides the means to model disease and therapy induced changes allowing for
new insights into single-cell spatially resolved tissue responses relevant to
human health.