Optimization Analysis of Particle Separation Parameters for a Standing Surface Acoustic Wave Acoustofluidic Chip

Han, Junlong; Hu, Hong; Lei, Yulin; Huang, Qiao; Chen, Fu; Gai, Chenhui; Jia, Ning

doi:10.1021/acsomega.2c04273

Cited by 5 publications

(1 citation statement)

References 57 publications

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“…Liu et al [ 45 ] summarized and classified particle motion in taSSAW microchannel based on analytical calculations. Han et al [ 46 ] focused on optimizing sorting parameters based on experimental observations and analytical modelling.…”

Section: Introductionmentioning

confidence: 99%

Investigation on submicron particle separation and deflection using tilted-angle standing surface acoustic wave microfluidics

Peng,

Lin,

et al. 2024

Heliyon

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Section: Introductionmentioning

confidence: 99%

Investigation on submicron particle separation and deflection using tilted-angle standing surface acoustic wave microfluidics

Peng,

Lin,

et al. 2024

Heliyon

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Characterization of AI-enhanced magnetophoretic transistors operating in a tri-axial magnetic field for on-chip bioparticle sorting

Abedini-Nassab,

Adibi,

Ahmadiasl

2024

Sci Rep

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We demonstrate two general classes of magnetophoretic transistors, called the “trap” and the “repel-and-collect” transistors, capable of switching single magnetically labeled cells and magnetic particles between different paths in a microfluidic chamber. Compared with prior work on magnetophoretic transistors operating in a two-dimensional in-plane rotating field, the use of a tri-axial magnetic field has the fundamental advantages of preventing particle cluster formation and better syncing of single particles with the general operating clock. We use finite element methods to investigate the energy distribution on the chip surface and to predict the particle behavior at various device geometries. We then fabricate the proposed transistors and compare the experimental results with the simulation predictions. We found that with gate electrical currents of ~ 40 mA for a transistor with proper geometry, complete switching of magnetic particles with diameters in the range of 8–15 μm is achieved. We show that the device is reliable and works well at different magnetic field strengths (50–100 Oe) and frequencies (0.05–0.5 Hz). We also employed an image processing code with a trained convolutional neural network to automate the proposed transistors for identifying and sorting particles with various sizes and magnetic susceptibilities with accuracies higher than 98%. The proposed transistors can be used in designing novel magnetophoretic circuits for important applications in biomedical microdevices and single-cell biology. Supplementary Information The online version contains supplementary material available at 10.1038/s41598-024-74761-2.

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Optimization analysis of the particle focusing and separation parameters of a sheathless microfluidic device using standing surface acoustic waves

Wang,

Lee,

et al. 2024

Physics of Fluids

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Flow-based particle separation usually requires a sheath flow for particle manipulation. Sheath fluid is a specialized buffer solution that directs the alignment of particles or cells into the center of the stream. By utilizing sheath flow, the particles or cells can be focused on the middle line of the microchannel, where they can be individually analyzed. However, the method requires an additional design for creating a suitable sheath flow. Purity and separation efficiency may also be influenced by the sheath flow. In this study, we present a sheathless device for particle focusing and separation using standing surface acoustic waves (SSAWs). The device comprises two regions: the focusing and separation regions. In the focusing region, particles in a continuous flow are aligned in the middle of the microchannel by SSAWs; in the separation region, tilted-angle SSAW-based particle separation is used to control particle migration. Varying particle sizes were focused in the focusing region and then separated in the separation region in the sheathless device. Experiments and simulations were also utilized to optimize a sheathless device. 10 and 20 μm particle focusing and separation were conducted in a sheathless device for the first time. We demonstrate that the separation of particles with a diameter of 10 and 20 μm has 90.8 ± 1.75% and 99.5 ± 0.8% separation efficiency, and 98 ± 3.4 and 97.9 ± 0.9% purity. Compared with other focusing and separation technologies, our device can also provide high purity, high separation efficiency, and high device density.

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Optimization Analysis of Particle Separation Parameters for a Standing Surface Acoustic Wave Acoustofluidic Chip

Cited by 5 publications

References 57 publications

Investigation on submicron particle separation and deflection using tilted-angle standing surface acoustic wave microfluidics

Investigation on submicron particle separation and deflection using tilted-angle standing surface acoustic wave microfluidics

Characterization of AI-enhanced magnetophoretic transistors operating in a tri-axial magnetic field for on-chip bioparticle sorting

Optimization analysis of the particle focusing and separation parameters of a sheathless microfluidic device using standing surface acoustic waves

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