Potentiation by red blood cells of shear-induced platelet aggregation: relative importance of chemical and physical mechanisms

Abstract

Abstract Evidence has been reported to indicate that red blood cells (RBCs) may potentiate platelet adherence and platelet aggregation (PAG) in different flow systems in vitro as well as hemostatic platelet plug formation in response to vascular injury. In this study, we demonstrate that RBCs enhance PAG induced by well-defined, low-intensity, uniform, laminar shear stress. Potentiation by RBCs of shear-induced PAG was associated with appreciable loss of adenine nucleotides from 14C- adenine-labeled RBCs, the extent of which increased with increasing RBC concentration. The concentrations of RBC-derived ADP measured in the medium after shear, as determined by both high pressure liquid chromatography and the luciferin/luciferase system, were within the range of concentrations of ADP which may trigger PAG or potentiate PAG induced by low concentrations of other platelet agonists in the aggregometer. To assess the relative contribution of chemical (ADP) and physical (platelet surface transport) mechanisms in the RBC-mediated potentiation of shear-induced PAG, aliquots of citrated platelet-rich plasma (C-PRP) were exposed to shear stress in the presence of untreated RBCs or RBCs exposed to an antihemolytic concentration (5 mumol/L) of the membrane stabilizing agent, chlorpromazine (CPZ). Potentiation of shear-induced PAG in the RBC-CPZ system was significantly less than that in the untreated RBC system. However, CPZ- induced reduction of PAG potentiation was associated with an increase rather than a decrease in loss of adenine nucleotides from RBC. Furthermore, shear-induced PAG in C-PRP as well as ADP- and collagen- induced PAG in C-PRP in the aggregometer was significantly inhibited by 5 mumol/L CPZ, indicating that the observed reduced potentiation of shear-induced PAG by RBCs in the presence of CPZ was due to a direct inhibitory effect of the drug on platelets rather than a reduction of shear-induced liberation of ADP from RBCs. When aliquots of C-PRP were exposed to shear stress in the presence of RBCs completely depleted of ADP by fixation in 1% glutaraldehyde, potentiation of PAG was approximately half of that observed with intact RBCs. These findings indicate that both RBC-derived ADP and RBC-mediated platelet surface transport are involved in the potentiation by RBCs of PAG induced by laminar shear stress.