DYNAMIC REGULATION OF ERYTHROPOIESIS - A COMPUTER-MODEL OF GENERAL APPLICABILITY

Abstract

A mathematical model for the control of erythropoiesis was developed based on the balance between oxygen supply and demand at a renal oxygen detector which in turn controls erythropoietin release and red cell production. Tissue oxygen tension is regulated by adjustments of Hb levels resulting from the output of a renal-bone marrow controller. Special consideration given to the determinants of tissue oxygenation included evaluation of the influence of blood flow, capillary diffusion, O2 uptake and O2-hemoglobin affinity. A theoretical analysis of the overall control system is presented including: dynamic and steady-state responses, sensitivity analysis to determine the relative importance of parameters and their influence on model behavior properties of the model as a proportional controller, analysis of steady-state errors and effectiveness of feedback regulation. Computer simulations of altitude hypoxia, descent from altitude, red cell infusion and hemolytic anemia demonstrate the validity of the model for general human application.