[Molecular self-organization and multiple equilibrium systems].

We have compared different types of natural self-organizing systems: crystal-like formation of multi molecular systems were conferred with self-organization in active media and dissipative structure formation. The comparison revealed a common feature of all such systems. They all have bi-(multi-)stable states. We propose a hypothesis that self-organization is impossible in systems that could not have bi-(multi-) stable states.

Finite platelet size could be responsible for platelet margination effect.

Blood flows through vessels as a segregated suspension. Erythrocytes distribute closer to the vessel axis, whereas platelets accumulate near vessel walls. Directed platelet migration to the vessel walls promotes their hemostatic function. The mechanisms underlying this migration remain poorly understood, although various hypotheses have been proposed to explain this phenomenon (e.g., the available volume model and the drift-flux model). To study this issue, we constructed a mathematical model that predicts the platelet distribution profile across the flow in the presence of erythrocytes. This model considers platelet and erythrocyte dimensions and assumes an even platelet distribution between erythrocytes. The model predictions agree with available experimental data for near-wall layer margination using platelets and platelet-modeling particles and the lateral migration rate for these particles. Our analysis shows that the strong expulsion of the platelets from the core to the periphery of the blood vessel may mainly arise from the finite size of the platelets, which impedes their positioning in between the densely packed erythrocytes in the core. This result provides what we believe is a new insight into the rheological control of platelet hemostasis by erythrocytes.

Platelet adhesion from shear blood flow is controlled by near-wall rebounding collisions with erythrocytes.

The efficacy of platelet adhesion in shear flow is known to be substantially modulated by the physical presence of red blood cells (RBCs). The mechanisms of this regulation remain obscure due to the complicated character of platelet interactions with RBCs and vascular walls. To investigate this problem, we have created a mathematical model that takes into account shear-induced transport of platelets across the flow, platelet expulsion by the RBCs from the near-wall layer of the flow onto the wall, and reversible capture of platelets by the wall and their firm adhesion to it. This model analysis allowed us to obtain, for the first time to our knowledge, an analytical determination of the platelet adhesion rate constant as a function of the wall shear rate, hematocrit, and average sizes of platelets and RBCs. This formula provided a quantitative description of the results of previous in vitro adhesion experiments in perfusion chambers. The results of the simulations suggest that under a wide range of shear rates and hematocrit values, the rate of platelet adhesion from the blood flow is mainly limited by the frequency of their near-wall rebounding collisions with RBCs. This finding reveals the mechanism by which erythrocytes physically control platelet hemostasis.

[From nonequilibrium thermodynamics to nonlinear dynamics]. / Ot neravnovesnoi termodinamiki k nelineinoi dinamike.

Differences between the thermodynamic and kinetic approaches were discussed by using a system with two or more different steady states as an example. It was shown that the behavior of such systems can be described adequately by the kinetic approach only.

Alamethicin as a permeabilizing agent for measurements of Ca(2+)-dependent ATPase activity in proteoliposomes, sealed membrane vesicles, and whole cells.

The channel-forming antibiotic peptide alamethicin was used in measurements of Ca-ATPase activity in sarcoplasmic reticulum (SR) vesicles, proteoliposomes containing Ca(2+)-ATPase from SR, and native human platelets. Alamethicin was used as a permeabilizing agent providing for a free access of the whole cells or sealed vesicles interiors for ions, ATP, and other reactants. The experiments were carried out with the use of alamethicin preparations obtained in our laboratory and that purchased from the Upjohn Company (antibiotic U-22,324). A comparative study of the effects of Ca(2+)-ionophore A23187 and alamethicin was performed on native SR vesicles containing Ca(2+)-ATPase molecules with right orientation and SR vesicles treated with cholate in order to randomize Ca(2+)-ATPase molecules orientation in the membrane. It was found out that alamethicin, like A-23187, prevents the ATP-dependent Ca2+ accumulation by the vesicles and therefore activates the Ca(2+)-ATPase. Maximal specific activities of the Ca(2+)-ATPase in native SR vesicles in the presence of either alamethicin, or A23187, or both of them, are equal in all cases to 20 activity units (mumol Pi per min per mg protein). The operative range of alamethicin concentrations is 5-25 micrograms/ml and is a little wider than that for A23187. The ATPase activity of the SR vesicles treated with cholate reached 20 units in the presence of alamethicin while in the presence of A23187 it was only 10 units. These data suggest that alamethicin unlike A23187 allows ATP to reach the ATPase's active centers from the inside of the SR vesicles with 'randomized' membranes, the ATP transport through the membrane not being the rate-limiting stage of ATP hydrolysis. It was shown that diffusion flux of ATP through a BLM in the presence of alamethicin may reach 10% of the flux through the hole without the BLM. With the use of alamethicin it was found out that the quality of randomization of the ATPase molecules orientation in the membrane depends on the proteoliposome preparation technique. The ATP transport through the alamethicin pores makes possible the use of alamethicin in accurate measurements of Ca(2+)-ATPase activity in whole cells. A method was developed for determination of the activity of human platelets was found to be 90-100 nmol Pi per min per mg protein.

[Mechanical oscillations and dynamic organization of biomembranes]. / Mekhanicheskie kolebaniia i dinamicheskaia organizatsiia biomembran.

Biological membranes are considered as mechanochemical active media. A hypothesis is advanced according to which the biomembranes are dimeric distributed non-equilibrium systems. They provide conjugated functioning of energy transducers by means of mechanical oscillations. Transmembrane currents of substance and energy stimulate in the membranes modes determining space and time organization of the membranes characteristic of dissipative structures. The mechano-chemical conjugation of all the processes is suggested to be the physical basis of their cooperativity. Critical wavelengths for basic modes and their energetic parameters are evaluated.