ABSTRACT
We consider in this paper the problem of derivation and regularization of higher (in Knudsen number) equations of hydrodynamics. The author's approach based on successive changes of hydrodynamic variables is presented in more detail for the Burnett level. The complete theory is briefly discussed for the linearized Boltzmann equation. It is shown that the best results in this case can be obtained by using the 'diagonal' equations of hydrodynamics. Rigorous estimates of accuracy of the Navier-Stokes and Burnett approximations are also presented.This article is part of the theme issue 'Hilbert's sixth problem'.
ABSTRACT
We propose a kinetic model of the aggregation process in a system consisting of two different types of particles. Aggregating particles (cells) are polyvalent and bear on the surface a huge number of binding sites for the other type of particles, ligands. The ligand is bivalent and has two identical active sites for binding to cells. The cross-linking of the cells by the ligands causes the aggregation phenomenon called agglutination. We obtained the analytical solution of this model task describing the time dependence of the aggregate mean size versus the composition of the system. The comparison of the analytical solution with the experimental data for the agglutination of bacterial cells by bivalent antibodies shows that the main factors affecting agglutination were correctly taken into account.
Subject(s)
Cell Aggregation/physiology , Models, Biological , Bacterial Adhesion/physiology , MathematicsABSTRACT
A study is presented of the central hemodynamics, renal function and water-salt metabolism in 42 patients with ischemic heart disease and chronic circulatory insufficiency (grades I and II) and revealed a deterioration of these indices in this categories of patients manifested in a retention of sodium, deterioration of central hemodynamics after increase of venous inflow.
