Role of erythrocyte‐ vs. wall‐derived signals in flow regulation in heterogeneous microvascular networks

Postulated mechanisms for metabolic flow regulation are examined using a theoretical model to simulate blood flow, mass transport and vascular responses in heterogeneous microvascular networks. The model accounts for myogenic, shear‐dependent, and metabolic flow regulation. Metabolic signals are assumed to be propagated upstream along vessel walls via a conducted response. Arteriolar tone is assumed to depend on the conducted metabolic signal as well as local wall shear stress and wall tension. In heterogeneous networks, unequal partition of hematocrit at diverging bifurcations can lead to low hematocrit in low‐flow vessels. If the metabolic signal is generated solely by an erythrocyte‐dependent mechanism, such vessels then experience a reduced metabolic signal and may constrict further, leading to further decreases in hematocrit and oxygen delivery. Inclusion of a metabolic signal dependent on oxygen levels at the vessel walls can prevent this effect. The different functional ranges of oxygen tension at which these signals operate suggest a role for both types of signals in flow regulation. Supported by NIH grant HL070657.