Blood advancing in living capillaries (5 to 10 m in diameter) and in the adjoining arterioles and venules (10 to 25 m in diameter) itself represents a specific substance hardly comparable with fluids in a usual understanding of this term. Its greatest part comprises the deformed red blood cells (RBCs) whose size is similar to luminal diameters of the microvessels. The RBCs (comprising great majority of the forming elements in microvessels) are disposed in the normal flow not chaotically, but in a certain order that was identified therefore as "blood flow structure (or structuring) in microvessels" [1][2][3].The specific regime of the RBCs flow in blood vessels changes from larger to smaller luminal diameters. Thus in vessels larger than 0.2 mm, the blood flow can be treated as a homogenous suspension with little error. By contrast, in arterioles or venules smaller than 25 m, and especially in capillaries (whose diameters are smaller than 8 m in humans), the RBCs are not uniformly dispersed, especially because of the presence of a parietal plasma layer containing no cells; thus the blood flow is specifically structured (Fig. 1). Disorders of this kind inevitably lead to the disturbance of normal blood rheological properties in the microvessels.Japanese Journal of Physiology Vol. 51, No. 1, 2001 19Japanese Journal of Physiology, 51, 19-30, 2001 Key words: RBC axial flow, parietal plasma layer, RBC aggregation, RBC deformation, plasma viscosity.
Abstract:The review article deals with phenomena of the blood flow structure (structuring) in narrow microvessels-capillaries and the adjacent arterioles and venules. It is particularly focused on the flow behavior of red blood cells (RBCs), namely, on their specific arrangements of mutual interaction while forming definite patterns of self-organized microvascular flow. The principal features of the blood flow structure in microvessels, including capillaries, include axial RBC flow and parietal plasma layer, velocity profile in larger microvessels, plug (or bolus) flow in narrow capillaries, and deformation and specific behavior of the RBCs in the flow. The actual blood flow structuring in microvessels seems to be a most significant factor in the development of pathological conditions, including arterial hypertension, brain and cardiac infarctions, inflammation, and many others. The blood flow structuring might become a basic concept in determining the blood rheological properties and disorders in the narrow microvessels. No solid theoretical (biorheological) basis of the blood flow structuring in microvessel has been found, but in the future it might become a foundation for a better understanding of the mechanisms of these properties under normal and pathological conditions in the narrowest microvessels 5 to 25 m large. It is also a topic for further biorheological research directed to find the background of actual physiopathological phenomena in the microcirculation.
