Journal
JOURNAL OF MICROELECTROMECHANICAL SYSTEMS
Volume 32, Issue 2, Pages 184-194Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/JMEMS.2023.3234760
Keywords
Magnetic separation; Microfluidics; Magnetic devices; Magnetic resonance imaging; Permanent magnets; Magnetic flux; Magnetic domains; Permanent magnet; NdFeB; magnetic particle; magnetophoresis; PMMA; PDMS; microfluidics
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In this study, a cost-effective, scalable, and rapid technique for fabricating a robust and high-performance on-chip positive magnetophoretic system is demonstrated. The system combines a thick patterned permanent magnet and a microfluidic channel on a single PMMA substrate for on-chip manipulation of magnetic particles. The magnet pattern design exerts a spatially varying magnetic force on the particles in the channel, enabling capturing at specific locations. The device geometry is optimized using FEM simulations to prevent blockage and simplify fabrication. A 1.5-fold enhancement in trapping efficiency is observed at a lower flow rate of 9 μl/min, resulting in 94.5% trapping efficiency.
In this work, we demonstrate a cost-effective, scalable, and rapid technique to fabricate a robust, high-performance on-chip positive magnetophoretic system. The system incorporates a thick patterned permanent magnet and microfluidic channel on a single polymethyl methacrylate (PMMA) substrate for on-chip manipulation of magnetic particles (MPs). Using the suitable patterning of the magnet, a spatially varying magnetic force is exerted onto the MPs in the channel, which is pertinent for capturing the MPs at specific locations. The device geometry is optimized using FEM simulations to prevent any blockage in the channel due to the accumulation of the MPs and ease the fabrication process. The similar to 1.5-fold enhancement in the trapping efficiency is observed upon lowering the flow rate from 15 mu l/min to 9 mu l/min, leading to 94.5% trapping efficiency at a lower flow rate of 9 mu l/min. [2022-0173]
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