Biomechanics and biorheology of red blood cells in sickle cell anemia

Sickle cell anemia (SCA) is an inherited blood disorder that causes painful crises due to vaso-occlusion of small blood vessels. The primary cause of the clinical phenotype of SCA is the intracellular polymerization of sickle hemoglobin resulting in sickling of red blood cells (RBCs) in deoxygenated conditions. In this review, we discuss the biomechanical and biorheological characteristics of sickle RBCs and sickle blood as well as their implications toward a better understanding of the pathophysiology and pathogenesis of SCA. Additionally, we highlight the adhesive heterogeneity of RBCs in SCA and their specific contribution to vaso-occlusive crisis.     

Rheological characterization of culture broth containing the exopolysaccharide PS-EDIV from Sphingomonas pituitosa

Sphingomonas pituitosa excretes the capsular exopolysaccharide PS-EDIV into the culture broth augmenting considerably its fluid viscosity. Since this change particularly affects key processes like mixing and transport during the microbial production, this work was aimed at the rheological characterization of the polymer-containing culture broth of S. pituitosa. The study included investigations on basic properties of the culture broth, but also on the dependence of the biomass–polymer-solution properties on different physicochemical post-cultivation treatment steps like variations of temperature, pH-value or concentration of salts. The essential result is the characterization of the viscoelastic behavior of the culture broth, which was more gel-like than sol-like and exhibited slight elastic properties. This rheological behavior showed that the PS-EDIV culture broth formed non-Newtonian fluids, indicating that it is a pseudoplastic biopolymer, with yield stress appearance and exhibits thixotropic properties. Rheograms were fitted to the Herschel–Bulkley model. The amplitude sweep revealed a deformation of 21% as the limiting value of the linear viscoelastic interval. Furthermore, the PS-EDIV culture broth showed a high viscosity which was strongly influenced by salt type and concentration but weakly influenced by temperature and pH-value within the investigated experimental boundaries.     

Influence of erythrocyte aggregation on radial migration of platelet-sized spherical particles in shear flow

Blood platelets when activated are involved in the mechanisms of hemostasis and thrombosis, and their migration toward injured vascular endothelium necessitates interaction with red blood cells (RBCs). Rheology co-factors such as a high hematocrit and a high shear rate are known to promote platelet mass transport toward the vessel wall. Hemodynamic conditions promoting RBC aggregation may also favor platelet migration, particularly in the venous system at low shear rates. The aim of this study was to confirm experimentally the impact of RBC aggregation on platelet-sized micro particle migration in a Couette flow apparatus. Biotin coated micro particles were mixed with saline or blood with different aggregation tendencies, at two shear rates of 2 and 10 s⁻¹ and three hematocrits ranging from 20 to 60%. Streptavidin membranes were respectively positioned on the Couette static and rotating cylinders upon which the number of adhered fluorescent particles was quantified. The platelet-sized particle adhesion on both walls was progressively enhanced by increasing the hematocrit (p < 0.001), reducing the shear rate (p < 0.001), and rising the aggregation of RBCs (p < 0.001). Particle count was minimum on the stationary cylinder when suspended in saline at 2 s⁻¹ (57 ± 33), and maximum on the rotating cylinder at 60% hematocrit, 2 s⁻¹ and the maximum dextran-induced RBC aggregation (2840 ± 152). This fundamental study is confirming recent hypotheses on the role of RBC aggregation on venous thrombosis, and may guide molecular imaging protocols requiring injecting active labeled micro particles in the venous flow system to probe human diseases.