A rotating stirrer achieved maximum platelet aggregation at a critical shear rate of 3100 s−1, with a wide stirrer shortening the time to maximum aggregation to 30 s versus 180 s for a narrow stirrer.
A rotating stirrer in a microfluidic chamber provides effective, controllable shear stimulation for activating platelets and inducing aggregation for platelet function testing.
High-shear stimulation is well known as one of the key factors affecting platelet activation and aggregation, which can lead to the formation of a thrombus. In one of our previous studies, we introduced migration distance-based platelet function analysis in a microfluidic system. In this study, we set out to examine the effects of stirring on shear-induced platelet activation and aggregation in a chamber system by using a rotating stirrer. We found that the rotating stirrer caused not only rotational shear flow but also a strong radial secondary flow. The latter flow led to efficient mixing in the chamber. Moreover, the rotational flow led to the generation of shear stress, the magnitude of which can be controlled to activate the platelets. Activated platelets tend to aggregate themselves. The maximum platelet aggregation was observed at a critical shear rate of 3100 s−1, regardless of the stirrer shape. Furthermore, the time taken to attain maximum aggregation was significantly shortened when using a wide stirrer (30 s) instead of a narrow one (180 s). When using a flat stirrer, the non-uniform shear field in the chamber system was resolved with the radial secondary flow-induced mixing; thus, most of the platelets were homogenously activated. The stirring-induced platelet activation mechanism was experimentally confirmed in a microfluidic system for a platelet aggregation test while monitoring the migration distance until the microfluidic channel is occluded. Our findings indicate that the present system, consisting of a rotating stirrer and a confined chamber, provides effective shear stimulation for activating platelets and inducing platelet aggregates.
Lee et al. (Tue,) conducted a other in Platelet activation and aggregation. Rotating stirrer vs. Narrow stirrer was evaluated on Platelet aggregation. A rotating stirrer achieved maximum platelet aggregation at a critical shear rate of 3100 s−1, with a wide stirrer shortening the time to maximum aggregation to 30 s versus 180 s for a narrow stirrer.
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