Investigating the Performance of the Multi-Lobed Leaf-Shaped Oscillatory Obstacles in Micromixers Using Bulk Acoustic Waves (BAW): Mixing and Chemical Reaction

Kordzadeh-Kermani, Vahid; Dartoomi, Hossein; Azizi, Mina; Ashrafizadeh, Seyed Nezameddin; Madadelahi, Masoud

doi:10.3390/mi14040795

Cited by 8 publications

(2 citation statements)

References 39 publications

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“…Microfluidics is one of the main paths towards faster, less expensive, POC PCR systems with a smaller footprint as it allows for the miniaturization of fluidic pathways and PCR reactor size while increasing the reactor’s surface-to-volume ratio [ 8 , 9 ]. It also reduces the amount of reagents used and lowers the sample volume required [ 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Rational PCR Reactor Design in Microfluidics

Madadelahi

Madou

2023

Micromachines

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Limit of detection (LOD), speed, and cost for some of the most important diagnostic tools, i.e., lateral flow assays (LFA), enzyme-linked immunosorbent assays (ELISA), and polymerase chain reaction (PCR), all benefited from both the financial and regulatory support brought about by the pandemic. From those three, PCR has gained the most in overall performance. However, implementing PCR in point of care (POC) settings remains challenging because of its stringent requirements for a low LOD, multiplexing, accuracy, selectivity, robustness, and cost. Moreover, from a clinical point of view, it has become very desirable to attain an overall sample-to-answer time (t) of 10 min or less. Based on those POC requirements, we introduce three parameters to guide the design towards the next generation of PCR reactors: the overall sample-to-answer time (t); lambda (λ), a measure that sets the minimum number of copies required per reactor volume; and gamma (γ), the system’s thermal efficiency. These three parameters control the necessary sample volume, the number of reactors that are feasible (for multiplexing), the type of fluidics, the PCR reactor shape, the thermal conductivity, the diffusivity of the materials used, and the type of heating and cooling systems employed. Then, as an illustration, we carry out a numerical simulation of temperature changes in a PCR device, discuss the leading commercial and RT-qPCR contenders under development, and suggest approaches to achieve the PCR reactor for RT-qPCR of the future.

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Section: Introductionmentioning

confidence: 99%

Rational PCR Reactor Design in Microfluidics

Madadelahi

Madou

2023

Micromachines

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“…When acoustic waves interact with the medium, two acoustic phenomena occur: acoustic streaming-induced forces and acoustic radiation forces, and one of these phenomena or a combination of them manipulates particles. Two different acoustic modes are commonly used to manipulate particles: surface acoustic wave (SAW) [ 13 ] and bulk acoustic wave (BAW) [ 14 ]. SAW is mainly generated by an interdigital transducer (IDT), where the acoustic signal propagates along the surface of a piezoelectric substrate, allowing the manipulation of tiny objects in a one- or two-dimensional plane.…”

Section: Introductionmentioning

confidence: 99%

Review of Ultrasonic Particle Manipulation Techniques: Applications and Research Advances

Wang

You

et al. 2023

Micromachines

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Ultrasonic particle manipulation technique is a non-contact label-free method for manipulating micro- and nano-scale particles using ultrasound, which has obvious advantages over traditional optical, magnetic, and electrical micro-manipulation techniques; it has gained extensive attention in micro-nano manipulation in recent years. This paper introduces the basic principles and manipulation methods of ultrasonic particle manipulation techniques, provides a detailed overview of the current mainstream acoustic field generation methods, and also highlights, in particular, the applicable scenarios for different numbers and arrangements of ultrasonic transducer devices. Ultrasonic transducer arrays have been used extensively in various particle manipulation applications, and many sound field reconstruction algorithms based on ultrasonic transducer arrays have been proposed one after another. In this paper, unlike most other previous reviews on ultrasonic particle manipulation, we analyze and summarize the current reconstruction algorithms for generating sound fields based on ultrasonic transducer arrays and compare these algorithms. Finally, we explore the applications of ultrasonic particle manipulation technology in engineering and biological fields and summarize and forecast the research progress of ultrasonic particle manipulation technology. We believe that this review will provide superior guidance for ultrasonic particle manipulation methods based on the study of micro and nano operations.

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