Abstract
The present work is inspired by the recent developments in laboratory experiments made
on chips, where the culturing of multiple cell species was possible. The model is based on coupled
reaction-diffusion-transport equations with chemotaxis and takes into account the interactions among
cell populations and the possibility of drug administration for drug testing effects. Our effort is
devoted to the development of a simulation tool that is able to reproduce the chemotactic movement
and the interactions between different cell species (immune and cancer cells) living in a microfluidic
chip environment. The main issues faced in this work are the introduction of mass-preserving and
positivity-preserving conditions, involving the balancing of incoming and outgoing fluxes passing
through interfaces between 2D and 1D domains of the chip and the development of mass-preserving
and positivity preserving numerical conditions at the external boundaries and at the interfaces
between 2D and 1D domains.
Anno
2021
Autori IAC
Tipo pubblicazione
Altri Autori
Elishan C. Braun; Gabriella Bretti; Roberto Natalini
Editore
MDPI
Rivista
Mathematics