Your search keyword '"Wälti C"' showing total 5 results

1. Rapid cell separation with minimal manipulation for autologous cell therapies.

Author

Smith AJ, O'Rorke RD, Kale A, Rimsa R, Tomlinson MJ, Kirkham J, Davies AG, Wälti C, and Wood CD

Subjects

Cell Separation instrumentation, Cells, Cultured, Dental Pulp cytology, Electrophoresis instrumentation, Electrophoresis methods, Humans, Mesenchymal Stem Cells cytology, Microfluidics instrumentation, Saccharomyces cerevisiae cytology, Sonication instrumentation, Sonication methods, Cell Separation methods, Microfluidics methods

Abstract

The ability to isolate specific, viable cell populations from mixed ensembles with minimal manipulation and within intra-operative time would provide significant advantages for autologous, cell-based therapies in regenerative medicine. Current cell-enrichment technologies are either slow, lack specificity and/or require labelling. Thus a rapid, label-free separation technology that does not affect cell functionality, viability or phenotype is highly desirable. Here, we demonstrate separation of viable from non-viable human stromal cells using remote dielectrophoresis, in which an electric field is coupled into a microfluidic channel using shear-horizontal surface acoustic waves, producing an array of virtual electrodes within the channel. This allows high-throughput dielectrophoretic cell separation in high conductivity, physiological-like fluids, overcoming the limitations of conventional dielectrophoresis. We demonstrate viable/non-viable separation efficacy of >98% in pre-purified mesenchymal stromal cells, extracted from human dental pulp, with no adverse effects on cell viability, or on their subsequent osteogenic capabilities., Competing Interests: The authors declare no competing financial interests.

Published

2017

2. A planar surface acoustic wave micropump for closed-loop microfluidics.

Author

Rimsa, R., Smith, A. J., Wälti, C., and Wood, C. D.

Subjects

MICROFLUIDICS, MICROPUMPS, ACOUSTICS, NANORODS, HEAT exchanger efficiency

Abstract

We have designed and characterized a simple Rayleigh-surface acoustic wave-based micropump, integrated directly with a fully enclosed 3D microfluidic system, which improves significantly the pumping efficiency within a coupled fluid whilst maintaining planar integration of the micropump and microfluidics. We achieve this by exploiting the Rayleigh-scattering angle of surface acoustic waves into pressure waves on contact with overlaid fluids, by designing a microfluidic channel aligned almost co-linearly with the launched pressure waves and by minimizing energy losses by reflections from, or absorption within, the channel walls. This allows the microfluidic system to remain fully enclosed--a pre-requisite for point-of-care applications--removing sources of possible contamination, whilst achieving pump efficiencies up to several orders of magnitude higher than previously reported, at low operating powers of 0.5 W. [ABSTRACT FROM AUTHOR]

Published

2017

3. Formation and manipulation of two-dimensional arrays of micron-scale particles in microfluidic systems by surface acoustic waves.

Author

Wood, C. D., Cunningham, J. E., O'Rorke, R., Wälti, C., Linfield, E. H., Davies, A. G., and Evans, S. D.

Subjects

PARTICLES, ACOUSTIC surface waves, STANDING waves, MICROFLUIDICS, RADIO frequency

Abstract

The two-dimensional concentration and manipulation of micron-scale particles by orthogonal, surface acoustic, standing waves is demonstrated. The particles are organized by liquid pressure waves in a microfluidic system over a piezoelectric substrate and form a uniform two-dimensional array with a spacing governed by the mechanical nodes of the two orthogonal, surface acoustic, standing waves. The nodal spacing can be controlled in each orthogonal direction independently by adjustment of the radio frequency applied to the separate acoustic wave transducers. This technique could be used to enhance the particle concentrations at sensing locations in DNA or protein array detectors. [ABSTRACT FROM AUTHOR]

Published

2009

4. Alignment of particles in microfluidic systems using standing surface acoustic waves.

Author

Wood, C. D., Evans, S. D., Cunningham, J. E., O’Rorke, R., Wälti, C., and Davies, A. G.

Subjects

MICROFLUIDICS, FLUID dynamics, PIEZOELECTRICITY, LATEX, PARTICLES, ACOUSTIC surface wave devices

Abstract

We report on the use of standing surface acoustic waves, formed on a single-crystal piezoelectric substrate, to organize micron-scale latex particles into an array comprising a series of lines in an adjacent microfluidic system. The lines of particles are formed parallel to the substrate surface and perpendicular to the surface acoustic wave vector. They extend across the width of the acoustic beam aperture, with a periodicity of one-half the surface acoustic wavelength. The position and spacing of the particle arrays can be altered by adjusting the acoustic wave frequency within the device passband. We discuss the mechanism responsible for the formation of the lines, which could be widely applicable to the alignment of microscopic objects held in suspension. [ABSTRACT FROM AUTHOR]

Published

2008

5. Acousto-microfluidics: Transporting microbubble and microparticle arrays in acoustic traps using surface acoustic waves.

Author

O'Rorke, R. D., Wood, C. D., Wälti, C., Evans, S. D., Davies, A. G., and Cunningham, J. E.

Subjects

MICROFLUIDICS, MICROBUBBLES, ACOUSTIC surface waves, MICROFLUIDIC devices, TRANSDUCERS, BANDWIDTHS

Abstract

We demonstrate that aqueous suspensions of microbubbles, formed into arrays using standing surface acoustic waves (SSAWs), can be transported by controlled modulation of the SSAW frequency. The array is repeatedly captured at a sequence of spatial positions along the acoustic beam path and long-range transportation is achieved by periodic cycling of the applied frequency across the transducer bandwidth. We also demonstrate that controllable alignment and transport can be achieved in a detachable microfluidic device, where the microfluidic channel, in which particle transport occurs, is separated from the piezoelectric substrate by an acoustic coupling gel. Proof-of-concept transport is first discussed using a test system of latex particles before the non-invasive manipulation technique is applied to arrays of microbubbles. We explore the role of acoustic radiation forces in the spatial control of particles by analysing the dynamics of particle manipulation by SSAWs. Our results highlight the exquisite control which we have over the position and transport of particles and we anticipate that this technique could find wide applications for the accurate and programmable, non-invasive ordering and transport of biological samples in microfluidic systems. [ABSTRACT FROM AUTHOR]

Published

2012