Dynamic Vortex Generation, Pulsed Injection, and Rapid Mixing of Blood Samples in Microfluidics Using the Tube Oscillation Mechanism

Thurgood, Peter; Needham, Scott; Pirogova, Elena; Peter, Karlheinz; Baratchi, Sara; Khoshmanesh, Khashayar

doi:10.1021/acs.analchem.2c05456

Cited by 5 publications

(3 citation statements)

References 49 publications

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“…It is worth noting that the rapid mixing of liquids can also be achieved using inertial microfluidic systems and active mechanisms. 26 Based on the centrifugal separation of plasma, we used centrifugal force to mix and drive the sample, automating the entire blood pretreatment process without an additional pump.…”

Section: Resultsmentioning

confidence: 99%

Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units

Wang

et al. 2023

Lab Chip

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Section: Resultsmentioning

confidence: 99%

Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units

Wang

et al. 2023

Lab Chip

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“…11 Thurgood et al reported a new mechanism for generating dynamic vortices in microfluidics at low static flow rates and demonstrated its application for cellular assays, fluid mixing, and pulsed injection. 12,13 new size-dependent particle trapping phenomenon in microvortices that enables tunable cell capture. 14 Liu et al proposed an acoustic microvortex-based strategy for cell capture, pairing, and fusion.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Instead, microvortices are of great use to microfluidic systems because they are conducive to the manipulation of fluids and particles, which have been used for the rapid and controlled synthesis of functional nanomaterials and tunable processing and analysis of particulate samples (such as cells and colloids). , For example, Zhang et al proposed flower-like micromixers based on acoustic microvortices for developing ZnO nanorod arrays . Thurgood et al reported a new mechanism for generating dynamic vortices in microfluidics at low static flow rates and demonstrated its application for cellular assays, fluid mixing, and pulsed injection. , Khojah et al uncovered a new size-dependent particle trapping phenomenon in microvortices that enables tunable cell capture . Liu et al proposed an acoustic microvortex-based strategy for cell capture, pairing, and fusion .…”

Section: Introductionmentioning

confidence: 99%

Vortex-Enhanced Microfluidic Chip for Efficient Mixing and Particle Capturing Combining Acoustics with Inertia

Lu,

Tan,

et al. 2024

Anal. Chem.

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Vortex-based microfluidics has received significant attention for its unique characteristics of high efficiency, flexible control, and label-free properties for the past decades. Herein, we present a vortex-based acousto-inertial chip that allows both fluid and particle manipulation within a significantly wider flow range and lower excitation voltage. Composed of contraction−expansion array structures and vibrating microstructures combined with bubbles and sharp edges, such a configuration results in more vigorous vortical fluid motions. The overall improvement in device performance comes from the synergistic effect of acoustics and inertia, as well as the positive feedback loop formed by vibrating bubbles and sharp edges. We characterize flow patterns in the microchannels by fluorescence particle tracer experiments and uncover single-and double-vortex modes over a range of sample flow rates and excitation voltages. On this basis, the ability of rapid and efficient sample homogenization up to a flow rate of 200 μL/min under an excitation voltage of 15 V pp is verified by a two-fluid fluorescence mixing experiment. Moreover, the recirculation motion of particles in microvortices is investigated by using a high-speed imaging system. We also quantitatively measure the particle velocity variation on the trajectory and illustrate the capturing mechanism, which results from the interaction of the microvortices, particle dynamics, and composite microstructure perturbations. Further utilizing the shear forces derived by microvortices, our acousto-inertial chip is demonstrated to lysis red blood cells (RBCs) in a continuous, reagent-free manner. The high controllability and multifunction of this technology allow for the development of multistep miniaturized "lab-on-chip" analytical systems, which could significantly broaden the application of microvortex technology in biological, chemical, and clinical applications.

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Tube Oscillation Drives Transitory Vortices Across Microfluidic Barriers

Thurgood,

Hawke,

Low

et al. 2023

Small Methods

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Here, the generation of dynamic vortices across microscale barriers using the tube oscillation mechanism is demonstrated. Using a combination of high‐speed imaging and computational flow dynamics, the cyclic formation, expansion, and collapse of vortices are studied. The dynamics of vortices across circular , triangular, and blade‐shape barriers are investigated at different tube oscillation frequencies. The formation of an array of synchronous vortices across parallel blade‐shaped barriers is demonstrated. The transient flows caused by these dynamic vortex arrays are harnessed for the rapid and efficient mixing of blood samples . A circular barrier scribed with a narrow orifice on its shoulder is used to facilitate the injection of liquid into the microfluidic channel, and its rapid mixing with the main flow through the dynamic vortices generated across the barrier. This approach facilitates the generation of vortices with desirable configurations, sizes, and dynamics in a highly controllable, programmable, and predictable manner while operating at low static flow rates.

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Dynamic Vortex Generation, Pulsed Injection, and Rapid Mixing of Blood Samples in Microfluidics Using the Tube Oscillation Mechanism

Cited by 5 publications

References 49 publications

Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units

Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units

Vortex-Enhanced Microfluidic Chip for Efficient Mixing and Particle Capturing Combining Acoustics with Inertia

Tube Oscillation Drives Transitory Vortices Across Microfluidic Barriers

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Dynamic Vortex Generation, Pulsed Injection, and Rapid Mixing of Blood Samples in Microfluidics Using the Tube Oscillation Mechanism

Cited by 5 publications

References 49 publications

Enrichment and detection of VEGF165 in blood samples on a microfluidic chip integrated with multifunctional units

Enrichment and detection of VEGF165 in blood samples on a microfluidic chip integrated with multifunctional units

Vortex-Enhanced Microfluidic Chip for Efficient Mixing and Particle Capturing Combining Acoustics with Inertia

Tube Oscillation Drives Transitory Vortices Across Microfluidic Barriers

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Product

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Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units

Enrichment and detection of VEGF₁₆₅ in blood samples on a microfluidic chip integrated with multifunctional units