Effect of Temperature and Flow Rate on the Cell-Free Area in the Microfluidic Channel

Abstract: Blood cell manipulation in microdevices is an interesting task for the separation of particles, by their size, density, or to remove them from the buffer, in which they are suspended, for further analysis, and more. This study highlights the cell-free area (CFA) widening based on experimental results of red blood cell (RBC) flow, suspended in a microfluidic device, while temperature and flow rate incrementally modify RBC response within the microflow. Studies of human red blood cell flow, at a concentration of… Show more

“…As previously mentioned, the use of microparticles in blood analogue fluids has been demonstrated to be essential to reproduce multiphase effects taking place in the human microcirculatory system, such as the cell-free layer (CFL) phenomena. The flow of the plasma analogue fluid (DMSO/W-PEO4M) with a 20% by volume of PDMS microparticles (45 : 1) was analyzed through a microfluidic channel with an important constriction, to simulate a microstenosis, and the results were compared with those of human blood, 55 also with a concentration of 20% by volume of RBCs. Fig.…”

“…12-a shows the design of the microfluidic device used in this study, the same as that used in Rodíguez-Villarreal et al . 55 to study the effect of temperature and the flow rate on the cell-free area. For the flow rates ( Q ) used in the in vitro experiments, this geometry gave rise to a high shear rate of around 10 4 s −1 , and allowed one to get a wide free layer of particles due to the flow inertia.…”

“…12 shows the results for RBCs suspended in plasma [Fig. 12(b)] 55 and PDMS (ratio 45 : 1) particles in the plasma analogue (DMSO/W-PEO4M) [Fig. 12(c) and (d)].…”

A particulate blood analogue based on artificial viscoelastic blood plasma and RBC-like microparticles at a concentration matching the human haematocrit

“…As previously mentioned, the use of microparticles in blood analogue fluids has been demonstrated to be essential to reproduce multiphase effects taking place in the human microcirculatory system, such as the cell-free layer (CFL) phenomena. The flow of the plasma analogue fluid (DMSO/W-PEO4M) with a 20% by volume of PDMS microparticles (45 : 1) was analyzed through a microfluidic channel with an important constriction, to simulate a microstenosis, and the results were compared with those of human blood, 55 also with a concentration of 20% by volume of RBCs. Fig.…”

“…12-a shows the design of the microfluidic device used in this study, the same as that used in Rodíguez-Villarreal et al . 55 to study the effect of temperature and the flow rate on the cell-free area. For the flow rates ( Q ) used in the in vitro experiments, this geometry gave rise to a high shear rate of around 10 4 s −1 , and allowed one to get a wide free layer of particles due to the flow inertia.…”

“…12 shows the results for RBCs suspended in plasma [Fig. 12(b)] 55 and PDMS (ratio 45 : 1) particles in the plasma analogue (DMSO/W-PEO4M) [Fig. 12(c) and (d)].…”

A particulate blood analogue based on artificial viscoelastic blood plasma and RBC-like microparticles at a concentration matching the human haematocrit

“…The movement of erythrocytes through blood vessels at elevated temperature is an interesting and useful task in separating blood cells from the buffer in which they are suspended based on their size or density, and for further analysis. It has been found that increasing the temperature increases the cell-free area near the blood vessel wall due to the inertia of the cell flow after the narrowing of the blood vessel [79]. The movement of erythrocytes through the blood vessel at elevated temperature in this way (increased area without cells near the blood vessel wall), enabled the production of a hybrid microfluidic device that uses hydrodynamic forces to separate human plasma from blood cells.…”

Impact of Temperature on Morphological Characteristics of Erythrocytes and Heart Weight: Experimental Study on Wistar Rats

“…There are other applications of membranes that do not require to focus at nanoscale, since the fluid dynamics at microscale can intrinsically separate particles from the suspending fluid. Rodríguez-Villarreal [7] et al focused on the effect of temperature and flow rate to increase the efficiency of separation taking advantage of microfluidic hydrodynamics effects. The accuracy of the performance of microfluidic-based particle separators is essential to achieve an equivalent performance in point-of-care devices compared to the conventional laboratory-based analytics.…”

Microfluidics and MEMS Technology for Membranes