Your search keyword '"Andrew J, deMello"' showing total 14 results

1. Thermoset polyester droplet-based microfluidic devices for high frequency generationElectronic supplementary information (ESI) available: Additional images of TPE microfluidics device and generated droplets. See DOI: 10.1039/c1lc20603f.

Author

Jin-young Kim, Andrew J. deMello, Soo-Ik Chang, Jongin Hong, and Danny O'Hare

Subjects

THERMOSETTING polymers, MICROFLUIDIC devices, FREQUENCIES of oscillating systems, POLYDIMETHYLSILOXANE, SHEAR (Mechanics), MECHANICAL behavior of materials, PLASMA gases

Abstract

The vast majority of droplet-based microfluidic devices are made from polydimethylsiloxane (PDMS). Unfortunately PDMS is not suitable for high frequency droplet generation at high operating pressure due to its low shear modulus. In this paper, we report the fabrication and testing of microfluidic devices using thermoset polyester (TPE). The optical characteristics of the fabricated devices were assessed and substrate resistance to pressure also investigated. TPE devices bonded using an O2plasma treated PET substrate at 76 °C were shown to function efficiently at pressures up to 18 MPa. TPE material retains many of the attractive features of PDMS such as ease of fabrication but significantly, has superior mechanical properties. The improved resistance of TPE to high pressures enabled investigation of high frequency droplet generation as a function of a wide range of flow-rates with three different oils as continuous phase. [ABSTRACT FROM AUTHOR]

Published

2011

2. A first step towards practical single cell proteomics: a microfluidic antibody capture chip with TIRF detectionPublished as part of a LOC themed issue dedicated to UK Research: Guest Editors Professors Hywel Morgan and Andrew deMello.

Author

Ali Salehi-Reyhani, Joseph Kaplinsky, Edward Burgin, Miroslava Novakova, Andrew J. deMello, Richard H. Templer, Peter Parker, Mark A. A. Neil, Oscar Ces, Paul French, Keith R. Willison, and David Klug

Subjects

PROTEOMICS, CYTOLOGY, MICROFLUIDICS, IMMUNOGLOBULINS, INTEGRATED circuits, CAVITATION, GENE transfection, P53 protein, SHOCK waves

Abstract

We have developed a generic platform to undertake the analysis of protein copy number from single cells. The approach described here is ‘all-optical’ whereby single cells are manipulated into separate analysis chambers using an optical trap; single cells are lysed by a shock wave caused by laser-induced microcavitation, and the protein released from a single cell is measured by total internal reflection microscopy as it is bound to micro-printed antibody spots within the device. The platform was tested using GFP transfected cells and the relative precision of the measurement method was determined to be 88%. Single cell measurements were also made on a breast cancer cell line to measure the relative levels of unlabelled human tumour suppressor protein p53 using a chip incorporating an antibody sandwich assay format. These results suggest that this is a viable method for measuring relative protein levels in single cells. [ABSTRACT FROM AUTHOR]

Published

2011

3. Non-emissive colour filters for fluorescence detectionPublished as part of a LOC themed issue dedicated to UK Research: Guest Editors Professors Hywel Morgan and Andrew deMello.Electronic supplementary information (ESI) available: ESI Fig. 1–3. See DOI: 10.1039/c0lc00642d

Author

Mikihide Yamazaki, Oliver Hofmann, Gihan Ryu, Li Xiaoe, Tai Kyu Lee, Andrew J. deMello, and John C. deMello

Subjects

MICROFABRICATION, COLOR, POROUS materials, NANOSTRUCTURED materials, METALLIC oxides, MONOMOLECULAR films, DYES & dyeing, EXCITON theory, MICROFLUIDIC devices

Abstract

We describe a simple technique for fabricating non-emissive colour filters based on the sensitisation of a highly porous nanostructured metal-oxide film with a monolayer of dye molecules. Ultrafast electron transfer at the oxide/dye interface induces efficient quenching of photogenerated excitons in the dye, reducing the photoluminescence quantum yield by many orders of magnitude. The resultant filters exhibit much less autofluorescence than conventional colour filters (where the chromophore is dispersed in a glass or polymer host), and are a viable low cost alternative to interference filters for microfluidic devices and other applications requiring non-emissive filtering. [ABSTRACT FROM AUTHOR]

Published

2011

4. Static microdroplet arrays: a microfluidic device for droplet trapping, incubation and release for enzymatic and cell-based assaysElectronic supplementary information (ESI) available: Details of protein production, data traces for kinetic measurements of several static droplets, raw data traces for multiple arrays, description of the movie showing release of droplets. See DOI: 10.1039/b813709a

Author

Ansgar Huebner, Dan Bratton, Graeme Whyte, Min Yang, Andrew J. deMello, Chris Abell, and Florian Hollfelder

Subjects

MICROFLUIDIC devices, DROPLETS, FLUID dynamics, CELL aggregation, ENZYME kinetics, BIOCHEMISTRY

Abstract

We describe the design, fabrication and use of a single-layered poly(dimethylsiloxane) microfluidic structure for the entrapment and release of microdroplets in an array format controlled entirely by liquid flow. Aqueous picoliter droplets are trapped en masse and optically monitored for extended periods of time. Such an array-based approach is used to characterize droplet shrinkage, aggregation of encapsulated E. colicells and enzymatic reactions. We also demonstrate that trapped droplets may be recovered from the microfluidic array for further processing. [ABSTRACT FROM AUTHOR]

Published

2009

5. Pillar-induced droplet merging in microfluidic circuitsIn honour of Andreas Manz on his retirement as Chair of the Lab on a ChipEditorial Board.Electronic supplementary information (ESI) available: Movies 1–3. See DOI: 10.1039/b813325e.

Author

Xize Niu, Shelly Gulati, Joshua B. Edel, and Andrew J. deMello

Subjects

MICROFLUIDICS, INTEGRATED circuits, MICROFLUIDIC devices, SURFACE tension, SEPARATION (Technology), PRESSURE

Abstract

A novel method is presented for controllably merging aqueous microdroplets within segmented flow microfluidic devices. Our approach involves exploiting the difference in hydrodynamic resistance of the continuous phase and the surface tension of the discrete phase through the use of passive structures contained within a microfluidic channel. Rows of pillars separated by distances smaller than the representative droplet dimension are installed within the fluidic network and define passive merging elements or chambers. Initial experiments demonstrate that such a merging element can controllably adjust the distance between adjacent droplets. In a typical scenario, a droplet will enter the chamber, slow down and stop. It will wait and then merge with the succeeding droplets until the surface tension is overwhelmed by the hydraulic pressure. We show that such a merging process is independent of the inter-droplet separation but rather dependent on the droplet size. Moreover, the number of droplets that can be merged at any time is also dependent on the mass flow rate and volume ratio between the droplets and the merging chamber. Finally, we note that the merging of droplet interfaces occurs within both compressing and the decompressing regimes. [ABSTRACT FROM AUTHOR]

Published

2008

6. Microdroplets: A sea of applications?

Author

Ansgar Huebner, Sanjiv Sharma, Monpichar Srisa-Art, Florian Hollfelder, Joshua B. Edel, and Andrew J. deMello

Subjects

MICROFLUIDICS, MOLECULES, FLUID dynamics, PHYSICAL sciences, LIFE sciences, CHEMICAL reactions

Abstract

The exploitation of microdroplets produced within microfluidic environments has recently emerged as a new and exciting technological platform for applications within the chemical and biological sciences. Interest in microfluidic systems has been stimulated by a range of fundamental features that accompany system miniaturization. Such features include the ability to process and handle small volumes of fluid, improved analytical performance when compared to macroscale analogues, reduced instrumental footprints, low unit cost, facile integration of functional components and the exploitation of atypical fluid dynamics to control molecules in both time and space. Moreover, microfluidic systems that generate and utilize a stream of sub-nanolitre droplets dispersed within an immiscible continuous phase have the added advantage of allowing ultra-high throughput experimentation and being able to mimic conditions similar to that of a single cell (in terms of volume, pH, and salt concentration) thereby compartmentalizing biological and chemical reactions. This review provides an overview of methods for generating, controlling and manipulating droplets. Furthermore, we discuss key fields of use in which such systems may make a significant impact, with particular emphasis on novel applications in the biological and physical sciences. [ABSTRACT FROM AUTHOR]

Published

2008

7. Monolithically integrated dye-doped PDMS long-pass filters for disposable on-chip fluorescence detection.

Author

Oliver Hofmann, Xuhua Wang, Alastair Cornwell, Stephen Beecher, Amal Raja, Donal D. C. Bradley, Andrew J. deMello, and John C. deMello

Published

2006

8. Towards microalbuminuria determination on a disposable diagnostic microchip with integrated fluorescence detection based on thin-film organic light emitting diodes.

Author

Oliver Hofmann, Xuhua Wang, John C. deMello, Donal D. C. Bradley, and Andrew J. deMello

Published

2005

9. A method for rapid reaction optimisation in continuous-flow microfluidic reactors using online Raman spectroscopic detection .

Author

Shee-Ann LeungAuthors contributed equally to this work., Richard F. Winkle, Robert C. R. Wootton, and Andrew J. deMello

Published

2004

10. Thin-film polymer light emitting diodes as integrated excitation sources for microscale capillary electrophoresis.

Author

Joshua B. Edel, Nigel P. Beard, Oliver Hofmann, John C. deMello, Donal D. C. Bradley, and Andrew J. deMello

Published

2004

11. High-throughput confinement and detection of single DNA molecules in aqueous microdropletsElectronic supplementary information (ESI) available: Experimental details. See DOI: 10.1039/b917721c.

Author

Monpichar Srisa-Art, Andrew J. deMello, and Joshua B. Edel

Subjects

DNA, MICROFLUIDICS, OPTICAL detectors, CHEMISTRY experiments, CHEMICAL detectors, CHEMICAL processes

Abstract

A droplet-based microfluidic system combined with high-sensitivity optical detection is used as a tool for high-throughput confinement and detection of single DNA molecules. [ABSTRACT FROM AUTHOR]

Published

2009

12. Accelerated synthesis of titanium oxide nanostructures using microfluidic chips.

Author

Ben F. Cottam, Siva Krishnadasan, Andrew J. deMello, John C. deMello, and Milo S. P. Shaffer

Subjects

TITANIUM dioxide, NANOSTRUCTURES, OXIDES, BATCH processing

Abstract

The synthesis of one-dimensional titanium oxide nanostructures has been accelerated by performing the reaction in a microfluidic environment as opposed to a classical batch process. [ABSTRACT FROM AUTHOR]

Published

2007

13. Continuous laminar evaporation: micron-scale distillation.

Author

Robert C. R. Wootton and Andrew J. deMello

Published

2004

14. Design of a solid-state nanopore-based platform for single-molecule spectroscopy.

Author

Jongin Hong, Yoonjae Lee, Guillaume A T, Joshua B Edel, and Andrew J deMello

Subjects

ELECTROMAGNETIC fields, DIELECTRICS, ALUMINUM, ELECTRONIC excitation

Abstract

We numerically assess the light propagation and distribution characteristics of electromagnetic fields on nanopores formed in dielectric and metal/dielectric membranes using a frequency-domain finite element method (3D full-wave electromagnetic field simulation). Results of such studies were used to identify aluminum as an ideal material for use in optically thick metal/dielectric membranes. The comparison between SiN and Al/SiN membranes (with and without a submicron sized aperture) was numerically and experimentally shown to verify the effect of optically thick metal layers on light propagation and fluorescence excitation. The cut-off behavior for Al/SiN membranes with varying pore diameters was investigated in terms of light propagation, distribution of electromagnetic fields, and light attenuation characteristics. [ABSTRACT FROM AUTHOR]

Published

2008