The paper originates from a scientific study focused on the mechanics of cell–cell interactions (CCI) and their impact on biological systems. These complex exchanges occur through direct contact or chemical signaling, allowing cells to influence the behavior of their neighbors and maintain tissue homeostasis. Researchers from Yale University utilized computational models and machine intelligence to map these pathways, specifically examining how gene expression changes in response to local environments. The data highlights specific ligand-receptor pairings across various brain cells, such as astrocytes and neurons, to illustrate how communication governs organ function. Ultimately, the study seeks to clarify the signaling cascades that drive development and the regulation of metabolic processes.
References:
- Xiao X, Zhang L, Zhao H, et al. Inferring spatial single-cell-level interactions through interpreting cell state and niche correlations learned by self-supervised graph transformer[J]. Nature Machine Intelligence, 2025: 1-17.
