Affiliations: Department of Bioengineering, University of California, San Diego, La Jolla, CA, USA | Department of Biomedical Engineering, Johns Hopkins University, Baltimore, MD, USA
Note: [] Address for correspondence: Paul C. Johnson, Ph.D., Dept. of Bioengineering, University of California, San Diego, La Jolla, CA 92093‐0412, USA. Tel.: +1 858 534 5686; Fax: +1 858 534 6896; E‐mail: [email protected].
Abstract: It has long been recognized that understanding the rheological properties of blood is essential to a full understanding of the function of the circulatory system. Given the difficulty of obtaining carefully controlled measurements in vivo, most of our current concepts of the flow behavior of blood in vivo are based on its properties in vitro. Studies of blood rheology in rotational and tube viscometers have defined the basic properties of blood and pointed to certain features that may be especially significant for understanding in vivo function. At the same time, differences between in vivo and in vitro systems combined with the complex rheological properties of blood make it difficult to predict in vivo blood rheology from in vitro studies. We have investigated certain flow properties of blood in vivo, using the venular network of skeletal muscle as our model system. In the presence of red blood cell aggregation, venous velocity profiles become blunted from the parabolic as in Poiseuille flow, as pseudo‐shear rate (= mean fluid velocity/vessel diameter) is decreased from ∼100 s−1 to 5 s−1. At control flow rates, the short distance between venular junctions does not appear to permit significant axial migration and red cell depletion of the peripheral fluid layer before additional red cells and aggregates are infused from a feeding tributary. Formation of a cell‐free plasma layer at the vessel wall and sedimentation in vivo are evident only at very low pseudo‐shear rates (<5 s−1). These findings may explain in large part observations in whole organs of increased venous resistance with reduction of blood flow.
