Tradeoffs between energy efficiency and mechanical response in fluid flow networks

TL;DR

This paper investigates the tradeoffs between energy efficiency and mechanical response in fluid flow networks, particularly in biological vasculature, revealing how vessel elasticity influences dissipation and response time.

Contribution

It introduces a model linking energy dissipation and response time in fluid networks, validated on human vasculature, highlighting their joint role in vascular network optimization.

Findings

Dissipation and response time follow power law scaling relations.

Vessel elasticity reduces energy loss but increases response time.

Response time is a critical factor in vascular network evolution.

Abstract

Transport networks are typically optimized, either by evolutionary pressures in biological systems or by human design in engineered structures. In the case of systems such as the animal vasculature, the transport of fluids is hindered by the inherent viscous resistance to flow while being kept in a dynamic state by the pulsatile nature of the heart and elastic properties of the vessel walls. While this imparted pulsatility necessarily increases the dissipation of energy caused by the resistance, the vessel elasticity helps to reduce overall dissipation by attenuating the amplitude of the pulsatile components of the flow. However, we find that this reduction in energy loss comes at the price of increasing the time required to respond to changes in the flow boundary conditions for vessels longer than a critical size. In this regime, dissipation and response time are found to follow a simple power law scaling relation both in single vessels as well as hierarchically structured networks. We validate the model in human vasculature and apply biologically relevant parameters to show that response time has to be considered alongside dissipation as an important fitness cost function in the evolutionary optimization of animal vascular networks.