Platelets are anucleate blood cells circulating in the bloodstream for up to 9 days in quiescent state. Upon vessel wall injury, platelets become activated, change their shape and adhere to the vessel wall and each other, thus forming a thrombus and preventing the blood loss. To get energy for these processes, they can use oxidative phosphorylation and glycolysis utilizing blood glucose, stored glycogen or fatty acids as fuel. Yet, there is no agreement in experimental data on platelet functioning in quiescent and activated states. This study is a systematic analysis of the energy abilities of quiescent platelets through mathematical modeling of their energy metabolism by Flux Balance Analysis (FBA). As a result of the FBA analysis we concluded that a platelet even in quiescent state utilizes blood glucose at high rate (0.1 mM/s), producing lactate from 99% of it and about 0.2 mM/s ATP from glycolysis and respiration. Such high fluxes of glucose are not always available due to platelet's glucose transporter (GLUT3)kinetic limitations. We positioned a "FBA" platelet in human glucose/insulin/glucagon PBPK/PD model to theoretically investigate platelet metabolism in close-to-real conditions. The main result of our study is that the stored glycogen could be daily used and resynthesized during platelet lifetime.

• 出版日期2016