Jeremy J. Hawkes scite author profile

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Continuous cell washing and mixing driven by an ultrasound standing wave within a microfluidic channel

Hawkes

et al. 2004

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Ultrasound standing wave radiation force and laminar flow have been used to transfer yeast cells from one liquid medium to another (washing) by a continuous field-flow fractionation (FFF) approach. Two co-flowing streams, a cell-free suspending phase (flow rate > 50% of the total flow-through volume) and a yeast suspension, were introduced parallel to the nodal plane of a 3 MHz standing wave resonator. The resonator was fabricated to have a single pressure nodal plane at the centre line of the chamber. Laminar flow ensured a stable interface was maintained as the two suspending phases flowed through the sound field. Initiation of the ultrasound transferred cells to the cell-free phase within 0.5 s. This particle transfer procedure circumvents the pellet formation and re-suspension steps of centrifuge based washing procedures. In addition, fluid mixing was demonstrated in the same chamber at higher sound pressures. The channel operates under negligible back-pressure (cross-section, 0.25 [times] 10 mm) and with only one flow convergence and one flow division step, the channel cannot be easily blocked. The force acting on the cells is small; less than that experienced in a centrifuge generating 100g. The acoustically-driven cell transfer and mixing procedures described may be particularly appropriate for the increasingly complex operations required in molecular biology and microbiology and especially for their conversion to continuous flow processes.

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Force field particle filter, combining ultrasound standing waves and laminar flow

Hawkes¹,

Coakley²

2001

Sensors and Actuators B: Chemical

208

124

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A silicon microfluidic ultrasonic separator

Harris

Hill

Beeby

et al. 2003

Sensors and Actuators B: Chemical

132

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Ultrasonic standing waves can be used to generate forces on particles within a fluid. Such forces have a number of potential applications in microfluidic devices. This paper describes a device that provides filtration on a microfluidic scale. It is microfabricated and uses ultrasound in the megahertz frequency range to concentrate particles at a node within the flow. It offers the possibility of a functional equivalent of a centrifugal separator for microfluidic systems. It is constructed using silicon and Pyrex, and hence is compatible with established microfabrication techniques. The modelling, design, fabrication and control of the device are discussed.

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Modelling of layered resonators for ultrasonic separation

2002

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Jeremy J. Hawkes

Forthcoming Lab on a Chip tutorial series on acoustofluidics: Acoustofluidics—exploiting ultrasonic standing wave forces and acoustic streaming in microfluidic systems for cell and particle manipulation

Continuous cell washing and mixing driven by an ultrasound standing wave within a microfluidic channel

Force field particle filter, combining ultrasound standing waves and laminar flow

A silicon microfluidic ultrasonic separator

Modelling of layered resonators for ultrasonic separation

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