Your search keyword '"Joie N. Marhefka"' showing total 2 results

1. Drag-reducing polymers diminish near-wall concentration of platelets in microchannel blood flow

Author

Joie N. Marhefka, Marina V. Kameneva, James F. Antaki, and Rui Zhao

Subjects

Blood Platelets, Erythrocytes, Microchannel, Polymers, Physiology, Chemistry, Microfluidics, Analytical chemistry, Blood flow, Article, Biomechanical Phenomena, Volumetric flow rate, Red blood cell, medicine.anatomical_structure, Physiology (medical), Blood Circulation, Image Processing, Computer-Assisted, medicine, Animals, Particle, Cattle, Platelet, Particle size, Particle Size, Blood vessel

Abstract

The accumulation of platelets near the blood vessel wall or artificial surface is an important factor in the cascade of events responsible for coagulation and/or thrombosis. In small blood vessels and flow channels this phenomenon has been attributed to the blood phase separation that creates a red blood cell (RBC)-poor layer near the wall. We hypothesized that blood soluble drag-reducing polymers (DRP), which were previously shown to lessen the near-wall RBC depletion layer in small channels, may consequently reduce the near-wall platelet excess. This study investigated the effects of DRP on the lateral distribution of platelet-sized fluorescent particles (diam. = 2 µm, 2.5 × 108/ml) in a glass square microchannel (width and depth = 100 µm). RBC suspensions in PBS were mixed with particles and driven through the microchannel at flow rates of 6–18 ml/h with and without added DRP (10 ppm of PEO, MW = 4500 kDa). Microscopic flow visualization revealed an elevated concentration of particles in the near-wall region for the control samples at all tested flow rates (between 2.4 ± 0.8 times at 6 ml/h and 3.3 ± 0.3 times at 18 ml/h). The addition of a minute concentration of DRP virtually eliminated the near-wall particle excess, effectively resulting in their even distribution across the channel, suggesting a potentially significant role of DRP in managing and mitigating thrombosis.

Published

2010

2. Drag reducing polymers improve tissue perfusion via modification of the RBC traffic in microvessels

Author

Rui Zhao, James F. Antaki, Sachin Velankar, Joie N. Marhefka, Zhongjun J. Wu, and Marina V. Kameneva

Subjects

Erythrocytes, Microchannel, medicine.diagnostic_test, Endothelium, Polymers, Viscosity, Physiology, Chemistry, Capillary action, Microcirculation, Microfluidics, Vasodilation, Nanotechnology, Hematocrit, Article, medicine.anatomical_structure, Physiology (medical), medicine, Biophysics, Vascular resistance, Animals, Blood Vessels, Cattle, Perfusion

Abstract

This paper reports a novel, physiologically significant, microfluidic phenomenon generated by nanomolar concen- trations of drag-reducing polymers (DRP) dissolved in flowing blood, which may explain previously demonstrated beneficial effects of DRP on tissue perfusion. In microfluidic systems used in this study, DRP additives were found to significantly mod- ify traffic of red blood cells (RBC) into microchannel branches as well as reduce the near-wall cell-free layer, which normally is found in microvessels with a diameter smaller than 0.3 mm. The reduction in plasma layer size led to attenuation of the so-called "plasma skimming" effect at microchannel bifurcations, increasing the number of RBC entering branches. In vivo, these changes in RBC traffic may facilitate gas transport by increasing the near vessel wall concentration of RBC and capillary hematocrit. In addition, an increase in near-wall viscosity due to the redirection of RBC in this region may potentially decrease vascular resistance as a result of increased wall shear stress, which promotes endothelium mediated vasodilation. These mi- crocirculatory phenomena can explain the previously reported beneficial effects of DRP on hemodynamics in vivo observed in many animal studies. We also report here our finding that DRP additives reduce flow separations at microchannel expansions, deflecting RBC closer to the wall and eliminating the plasma recirculation zone. Although the exact mechanism of the DRP effects on RBC traffic in microchannels is yet to be elucidated, these findings may further DRP progress toward clinical use.

Published

2009