Transport of drug particles in micropumps through novel actuation

Micropumps with various types of actuations have been used in lab-on-a-chip devices. In order to control the delivery of drug particles both in space and time and avoid clogging, other types of actuation mechanisms may be needed. In this study, a valveless micropump with novel actuation is proposed to transport particles for biomedical and environmental applications. The transport of drug particles through the designed valveless micropump is carried out through computational fluid dynamics combined with discrete particle transport methods. After convergence studies, the effects of actuation frequency, particle size and the resident times on the particle transport are investigated. Interestingly, both the actuation frequency and particle size have a strong effect in terms of resident times and the spatial distribution of the transported particles through the designed micropump. Based on the results obtained, the relationship between actuation frequency, fluid flow, and particle transport through the designed micropump is presented. The computational analysis presented demonstrates that it is possible to optimize the proposed valveless micropump design for specific delivery of drug particles for separation and sorting applications.

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