Abstract
AbstractModeling dynamics of gene regulatory networks using ordinary differential equations (ODEs) allow a deeper understanding of disease progression and response to therapy, thus aiding in intervention optimization. Although there exist methods to infer regulatory ODEs, these are generally limited to small networks, rely on dimensional reduction, or impose non-biological parametric restrictions — all impeding scalability and explainability. PHOENIX is a neural ODE framework incorporating prior domain knowledge as soft constraints to infer sparse, biologically interpretable dynamics. Extensive experiments - on simulated and real data - demonstrate PHOENIX’s unique ability to learn key regulatory dynamics while scaling to the whole genome.
Publisher
Cold Spring Harbor Laboratory
Reference74 articles.
1. Reconstructing data-driven governing equations for cell phenotypic transitions: integration of data science and systems biology;Physical Biology,2022
2. Learning causal networks using inducible tran-scription factors and transcriptome-wide time series;Molecular systems biology,2020
3. Mapping transcriptomic vector fields of single cells
4. Generative modeling of single-cell time series with PRESCIENT enables prediction of cell trajectories with interventions;Nature communications,2021
5. An exponential stability test for a messenger rna–micro rna ode model;University politehnica of bucharest scientific bulletin-series a-applied mathematics and physics,2020
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