Congestive feedback uniformly partitions red blood cells in the zebrafish microvasculature

Vascular networks are widely thought to be organized to traffic oxygen and dissolved chemicals to tissues as efficiently as possible. Yet the kinetics of oxygen disassociation require that red blood cells travel through each capillary at approximately the same rate, and it is not known how vascular networks realize uniform flow across fine vessels distributed at different distances from the heart. Here we study the trunk vessels of developing zebrafish embryos as a model for red blood cell partitioning in real vascular systems. Experimental measurements in a live zebrafish embryo show that fluxes are highly uniform between different vessels. Red blood cells partially clog the vessels that they flow through, so there is congestive feedback between the number of cells in a vessel and the flux into that vessel. Precisely controlling the congestive feedback creates uniform flow across distant segmental vessels. Although eliminating congestion is a key element in the design of efficient transport networks, this work suggests that microvasculature networks may target uniformity, rather than efficiency, and that they do so by creating and controlling congestion.