English

Spatial dynamic modelling to understand how dendritic cell clustering affects T cell activation

Cell Behavior 2026-04-21 v1

Abstract

The coordination of the immune system and its components is essential for the body to maintain a healthy status. Recent clinical studies show that breast cancer patients with high Dendritic cell clustering in tumour draining lymph nodes have improved survival outcomes, compared to those with a lower degree of clustering. These results suggest that a specific form of Dendritic cell clustering promotes T cell activation. However, the mechanistic effects of this spatial organisation is unclear. We develop a spatially dynamic model of T cells interacting with Dendritic cells within the lymph node. We present a novel probabilistic agent-based model (ABM) of T cells, and use it to derive the deterministic, phenotypically structured partial differential equation (PS-PDE) of T cell activation and motion. Using the PS-PDE, we derive analytic approximations of the expected T cell stimulation distribution, based on the topology and level of clustering of a given Dendritic cell population. Our analytic approximation enables us to identify T cell characteristics that benefit most from Dendritic cell clustering, to result in an enhanced stimulation distribution. We also perform a sensitivity analysis with our models to identify T cell characteristics that result in desirable T cell activation characteristics, such as rapid T cell activation, and robust heterogeneous T cell activation. Our key findings show that T cells with an intermediate level of stimulation uptake benefit most from higher levels of Dendritic cell clustering, activating with a comparable or greater abundance, and greater heterogeneity, when compared to T cells of a similar characteristic but with a lower level of Dendritic cell clustering.

Keywords

Cite

@article{arxiv.2604.17786,
  title  = {Spatial dynamic modelling to understand how dendritic cell clustering affects T cell activation},
  author = {Domenic P. J. Germano and Federico Frascoli and Robyn P. Araujo and Peter P. Lee and Peter S. Kim},
  journal= {arXiv preprint arXiv:2604.17786},
  year   = {2026}
}
R2 v1 2026-07-01T12:17:34.691Z