ID: 2111.04657

Distribution efficiency and structure of complex networks

November 8, 2021

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Georgios Gounaris, Miguel Ruiz Garcia, Eleni Katifori
Quantitative Biology
Nonlinear Sciences
Physics
Tissues and Organs
Adaptation and Self-Organizi...
Biological Physics

Flow networks efficiently transport nutrients and other solutes in many physical systems, such as plant and animal vasculature. In the case of the animal circulatory system, an adequate oxygen and nutrient supply is not guaranteed everywhere: as nutrients travel through the microcirculation and get absorbed, they become less available at the venous side of the vascular network. Ensuring that the nutrient distribution is homogeneous provides a fitness advantage, as all tissue gets enough supply to survive while waste is minimized. How do animals build such a uniform perfusing flow system? We propose a local adaptation rule for the vessel radii that is able to equalize perfusion, while minimizing energy dissipation to circulate the flow and the material cost. The rule is a combination of different objective cost functions that compete to produce complex network morphologies ranging from hierarchical architectures to uniform mesh grids, depending on how each cost is weighted. We find that our local adaptation rules are consistent with experimental data of the rat mesentery vasculature.

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