Microfluidics-based study on the damage pattern of red blood cells and VWF / 国际生物医学工程杂志

Objective:To investigate the effects of shear stress magnitude and exposure time on the damage of blood component erythrocytes and von willebrand factor (VWF) based on microfluidic technology.Methods:A blood shear platform was built based on a microfluidic chip, samples were prepared under different shear stress magnitudes and exposure time lengths, free hemoglobin assay experiments were performed on blood samples, the hemolysis indices of different samples were measured, and the relative molecular masses of different samples of VWF were analyzed by immunoblotting and chemiluminescence imaging.Results:The quantitative relationships between the hemolysis index and the degradation rate of high relative molecular mass VWF with shear stress and exposure time followed the power function model well.Conclusions:The microfluidic experimental platform has the advantages of a precise and controllable internal microenvironment and easy and rapid detection, which can be used for the quantitative study of blood damage patterns.

VWF Damage Based on Novel Maglev Taylor-Couette Blood-Shearing Circulation Platform / 医用生物力学

Objective To study von Willebrand factor(VWF) damage based on a novel Maglev Taylor-Couette blood-shearing device. Methods The magnetic levitation (maglev) Taylor-Couette blood-shearing device was designed, and the blood-shearing platform was built. Fresh porcine blood was tested in circulation loop for 1 hour at laminar flow state. VWF damage was assessed by analyzing sample through Western blot and enzyme-linked immunosorbent assay. Results With the increase of exposure time and shear stress, a large number of high molecular weight VWF multimers were degraded into low molecular weight VWF. The maximum rate of degradation was 569%. When the shear stress increased from 18 Pa to 55 Pa, the ratio of VWF-Rco to VWF-Ag decreased from 45.7% to 32.8%. ConclusionsCompared with initial sample, the VWF damage was mainly manifested by the decrease of high molecular weight VWF and the decrease of VWF activity, and VWF-Ag did not change significantly. The novel maglev Taylor-Couette blood-shearing device can quantitatively control the flow parameters (exposure time and shear stress), and be used for blood damage research in vitro, thus providing references for the design and optimization of extracorporeal membrane oxygenation and blood pump.