Neuronal activity induces changes in blood flow by locally dilating vessels in the brain microvasculature. How can the local dilation of a single vessel increase flow-based metabolite supply, given that flows are globally coupled within microvasculature? Solving the supply dynamics for rat brain microvasculature, we find one parameter regime to dominate physiologically. This regime allows for robust increase in supply independent of the position in the network, which we explain analytically. We show that local coupling of vessels promotes spatially correlated increased supply by dilation.Vascular networks pervade all organs of animals and are the paradigm of adaptive transport networks. Their self-organized architecture continuously inspires the search for their underlying physical principles [1][2][3][4] and at the same time serves as a template for designing efficient networks in engineering [5]. The blood flowing through vessels transports nutrients, hormones, and metabolites to adjacent tissues. Metabolite exchange primarily occurs within the fine vessel meshwork formed by microvasculature. In the brain, local metabolite demand can abruptly rise due to an increase in neural activity [6], altering blood flow [7,8] in the same brain region, observable in fMRI [9]. During the process of increased neuronal activity, neurons signal their increased demand to adjacent astrocyte cells, which in turn trigger small ring muscles surrounding blood vessels to relax [10]. Thus, neural activity drives local dilation of a vessel [11,12], and hence regulates metabolite supply [7,13]. However, from a fluid dynamics perspective there is a mystery: blood vessels form a highly interconnected network in the microvasculature [8], resulting in a global coupling of blood flow. A single dilating vessel can potentially change the metabolite supply in a broad region of the networkand thus the local increase due to dilation is a function of specific network topology. Quantitatively, how much control over changes in blood-based supply resides in a single dilating vessel?Models considering metabolite spread in tissue date back more than a hundred years to A. Krogh [14]. Krogh's model estimates the supply pattern in a tissue enclosed by vessels assuming that supply is constant on all vessel walls. Yet, on a larger tissue scale, supply spatially varies along the vasculature since resources supplied upstream are not available downstream. Alternative models consider vessel-based transport [15], yet only diffusive transport is taken into account. The combined importance of advection and diffusion for transporting solutes in a single tube was discovered by G.I. Taylor [16,17], with subsequent work outlining modifications due to solute absorption at the tube boundary [18][19][20]. Yet, there has been much less work capturing the coupling of advection and diffusion in tubular network struc-tures [21,22], including solute absorption [23]. The impact of a dilating vessel is hard to estimate since not only the absorption dynamics on the level of sing...
