Acoustic Microfluidic Separation Techniques and Bioapplications: A Review

Gao, Yuan; Wu, Mengren; Lin, Yang; Xu, Jie

doi:10.3390/mi11100921

Cited by 77 publications

(67 citation statements)

References 123 publications

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“…SAWs are further subdivided into standing SAWs (SSAWs) and traveling SAWs (TSAWs). The key difference between bulk waves and standing waves are that bulk waves, generated by a piezoelectric transducer, propagate through the bulk of the microchannel chamber itself, while surface acoustic waves, generated by an interdigitated transducer, Preparation of Tissues and Heterogeneous Cellular Samples for Single-Cell Analysis DOI: http://dx.doi.org/10.5772/intechopen.100184 propagate through the bottom surface of the channel [113]. Acoustofluidic systems are frequently used to sort cells via deformability or other elastic properties.…”

Section: Label-free Sorting By Acoustophoretic Propertiesmentioning

confidence: 99%

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Preparation of Tissues and Heterogeneous Cellular Samples for Single-Cell Analysis

Welch¹,

Tripathi²

2021

Sample Preparation Techniques for Chemical Analysis

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While sample preparation techniques for the chemical and biochemical analysis of tissues are fairly well advanced, the preparation of complex, heterogenous samples for single-cell analysis can be difficult and challenging. Nevertheless, there is growing interest in preparing complex cellular samples, particularly tissues, for analysis via single-cell resolution techniques such as single-cell sequencing or flow cytometry. Recent microfluidic tissue dissociation approaches have helped to expedite the preparation of single cells from tissues through the use of optimized, controlled mechanical forces. Cell sorting and selective cellular recovery from heterogenous samples have also gained traction in biosensors, microfluidic systems, and other diagnostic devices. Together, these recent developments in tissue disaggregation and targeted cellular retrieval have contributed to the development of increasingly streamlined sample preparation workflows for single-cell analysis technologies, which minimize equipment requirements, enable lower processing times and costs, and pave the way for high-throughput, automated technologies. In this chapter, we survey recent developments and emerging trends in this field.

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Section: Label-free Sorting By Acoustophoretic Propertiesmentioning

confidence: 99%

“…They can be separated by size due to differences in forces that dominate at different particle sizes. Specifically, acoustic radiation dominates in larger particles while drag forces induced by acoustic streaming dominate in smaller ones [113].…”

Section: Bulk Standing Wavesmentioning

confidence: 99%

Preparation of Tissues and Heterogeneous Cellular Samples for Single-Cell Analysis

Welch¹,

Tripathi²

2021

Sample Preparation Techniques for Chemical Analysis

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“…The most commonly used forces are dielectric, 12,[25][26][27][28] magnetic, 6,9,13,22,23 hydrodynamic, 18,29,30 and acoustic. 16,19,27,[31][32][33][34] However, each of these methods exhibits fundamental limitations, such as the requirement of low flow rates or particle labelling. In this work, medium exchange is achieved by first trapping bacterial cells by acoustic forces and subsequently flushing the channel with a new medium such as ultrapure water.…”

Section: Introductionmentioning

confidence: 99%

Acoustofluidic Medium Exchange for Preparation of Electrocompetent Bacteria Using Channel Wall Trapping

Gerlt

Ruppen

Leuthner

et al. 2021

Preprint

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Transformation, i.e. reprogramming of bacteria by delivering exogenous genetic material (such as DNA) into the cytoplasm, is a key process in molecular engineering and modern biotechnology in general. Transformation is often performed by electroporation, i.e. creating pores in the membrane using electric shocks in a low conductivity environment. However, cell preparation for electroporation can be cumbersome as it requires the exchange of growth medium (high-conductivity) for low-conductivity medium, typically performed via multiple time-intensive centrifugation steps. To simplify and miniaturize this step, we developed an acoustofluidic device capable of trapping the bacterium Escherichia coli non-invasively for subsequent exchange of medium, which is challenging in acoustofludic devices due to detrimental acoustic streaming effects. With an improved etching process, we were able to produce a thin wall between two microfluidic channels, which, upon excitation, can generate streaming fields that complement the acoustic radiation force and therefore can be utilized for trapping of bacteria. Our novel design robustly traps Escherichia coli at a flow rate of 10 µL minute-1 and has a cell recovery performance of 47 ± 3 % after washing the trapped cells. To verify that the performance of the medium exchange device is sufficient, we tested the electrocompetence of the recovered cells in a standard transformation procedure and found a transformation efficiency of 8∙105 CFU per µg of plasmid DNA. Our device is a viable low-volume alternative to centrifugation-based methods and opens the door for miniaturization of a plethora of microbiological and molecular engineering protocols.

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“…The development of miniaturized laboratory instrumentations and procedures in portable, integrated automated systems in enhanced microfluidic platforms is mandatory to allow a widespread application of liquid biopsy in everyday use either in diagnostic or clinical practice [11][12][13][14]. Acoustophoretic devices among others [15][16][17][18][19][20] emerged in biomedical research, as well as in clinical and diagnostic fields [21,22], for the separation or trapping of particles and cells, the control of their trajectories or their encapsulation in droplets [23][24][25]. By this approach, particles subjected to an ultrasonic field, generated via bulk acoustic waves (BAW) or surface acoustic waves (SAW), are scattered or impinged by field waves, allowing the creation of an acoustic radiation force able to move particles towards the surrounding medium.…”

Section: Introductionmentioning

confidence: 99%

Focalization Performance Study of a Novel Bulk Acoustic Wave Device

et al. 2021

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This work illustrates focalization performances of a silicon-based bulk acoustic wave device applied for the separation of specimens owing to micrometric dimensions. Samples are separated in the microfluidic channel by the presence of an acoustic field, which focalizes particles or cells according to their mechanical properties compared to the surrounded medium ones. Design and fabrication processes are reported, followed by focalization performance tests conducted either with synthetic particles or cells. High focalization performances occurred at different microparticle concentrations. In addition, preliminary tests carried out with HL-60 cells highlighted an optimal separation performance at a high flow rate and when cells are mixed with micro and nanoparticles without affecting device focalization capabilities. These encouraging results showed how this bulk acoustic wave device could be exploited to develop a diagnostic tool for early diagnosis or some specific target therapies by separating different kinds of cells or biomarkers possessing different mechanical properties such as shapes, sizes and densities.

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Acoustic Microfluidic Separation Techniques and Bioapplications: A Review

Cited by 77 publications

References 123 publications

Preparation of Tissues and Heterogeneous Cellular Samples for Single-Cell Analysis

Preparation of Tissues and Heterogeneous Cellular Samples for Single-Cell Analysis

Acoustofluidic Medium Exchange for Preparation of Electrocompetent Bacteria Using Channel Wall Trapping

Focalization Performance Study of a Novel Bulk Acoustic Wave Device

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