在微通道中制造图案化磁性粒子及其在微搅拌器中的应用

Biosensors Pub Date : 2024-08-23 DOI:10.3390/bios14090408
Tianhao Li, Chen Yang, Zihao Shao, Ya Chen, Jiahui Zheng, Jun Yang, Ning Hu
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引用次数: 0

摘要

由于雷诺数极低,微流体通道内层流物质的混合主要依靠缓慢的分子间扩散,而芯片实验室应用中的各种快速反应和检测要求往往需要在短距离内高效混合流体。本文介绍了一种磁性柱形粒子制造装置,该装置能够制造出平面形状的粒子,然后利用这些粒子实现微通道内多种流体的快速混合。在颗粒制造过程中,脱气 PDMS 芯片具有自吸功能,可吸入含有紫外线固化粘合剂的磁粉,并将其分配到不同的微孔结构中。随后,施加外部磁场,并将芯片暴露在紫外光下,通过光固化大规模生产具有特定磁性能的颗粒。这种基于芯片的设备无需外部泵,可在 10 分钟内制造出数百个磁性粒子。与大多数颗粒制造方法相比,脱气 PDMS 方法可实现自吸和精确分配,从而实现对颗粒形状和大小的精确控制。制造出的双层磁性粒子具有扇形叶片和盘状结构,被置于微混合通道中。通过操纵磁场,颗粒被驱动运动,改变流动模式,实现流体混合。在芯片中雷诺数为 0.1 至 0.9 的条件下,水溶液中物质的混合指数超过 0.9。此外,对不同粘度的流体(包括 25 wt% 和 50 wt% 的甘油)进行的混合效率实验分析表明,混合指数超过了 0.85,这表明基于磁性颗粒快速旋转的微型搅拌器具有广泛的适用性。
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Fabrication of Patterned Magnetic Particles in Microchannels and Their Application in Micromixers
Due to the extremely low Reynolds number, the mixing of substances in laminar flow within microfluidic channels primarily relies on slow intermolecular diffusion, whereas various rapid reaction and detection requirements in lab-on-a-chip applications often necessitate the efficient mixing of fluids within short distances. This paper presents a magnetic pillar-shaped particle fabrication device capable of producing particles with planar shapes, which are then utilized to achieve the rapid mixing of multiple fluids within microchannels. During the particle fabrication process, a degassed PDMS chip provides self-priming capabilities, drawing in a UV-curable adhesive-containing magnetic powder and distributing it into distinct microwell structures. Subsequently, an external magnetic field is applied, and the chip is exposed to UV light, enabling the mass production of particles with specific magnetic properties through photo-curing. Without the need for external pumping, this chip-based device can fabricate hundreds of magnetic particles in less than 10 min. In contrast to most particle fabrication methods, the degassed PDMS approach enables self-priming and precise dispensing, allowing for precise control over particle shape and size. The fabricated dual-layer magnetic particles, featuring fan-shaped blades and disk-like structures, are placed within micromixing channels. By manipulating the magnetic field, the particles are driven into motion, altering the flow patterns to achieve fluid mixing. Under conditions where the Reynolds number in the chip ranges from 0.1 to 0.9, the mixing index for substances in aqueous solutions exceeds 0.9. In addition, experimental analyses of mixing efficiency for fluids with different viscosities, including 25 wt% and 50 wt% glycerol, reveal mixing indices exceeding 0.85, demonstrating the broad applicability of micromixers based on the rapid rotation of magnetic particles.
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