Customisable 3D printed microfluidics for integrated analysis and optimisation
The formation of smart Lab-on-a-Chip (LOC) devices featuring integrated sensing optics is currently hindered by convoluted and expensive manufacturing procedures. In this work, a series of 3D-printed LOC devices were designed and manufactured via stereolithography (SL) in a matter of hours. The spec...
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| Veröffentlicht in: | Lab on a chip 2016-01, Vol.16 (17), p.3362-3373 |
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| creator | Monaghan, T Harding, M. J Harris, R. A Friel, R. J Christie, S. D. R |
| description | The formation of smart Lab-on-a-Chip (LOC) devices featuring integrated sensing optics is currently hindered by convoluted and expensive manufacturing procedures. In this work, a series of 3D-printed LOC devices were designed and manufactured
via
stereolithography (SL) in a matter of hours. The spectroscopic performance of a variety of optical fibre combinations were tested, and the optimum path length for performing Ultraviolet-visible (UV-vis) spectroscopy determined. The information gained in these trials was then used in a reaction optimisation for the formation of carvone semicarbazone. The production of high resolution surface channels (100-500 μm) means that these devices were capable of handling a wide range of concentrations (9 μM-38 mM), and are ideally suited to both analyte detection and process optimisation. This ability to tailor the chip design and its integrated features as a direct result of the reaction being assessed, at such a low time and cost penalty greatly increases the user's ability to optimise both their device and reaction. As a result of the information gained in this investigation, we are able to report the first instance of a 3D-printed LOC device with fully integrated, in-line monitoring capabilities
via
the use of embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro channels.
3DP was used to produce a fluidic device with embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro-channels. |
| doi_str_mv | 10.1039/c6lc00562d |
| format | Article |
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via
stereolithography (SL) in a matter of hours. The spectroscopic performance of a variety of optical fibre combinations were tested, and the optimum path length for performing Ultraviolet-visible (UV-vis) spectroscopy determined. The information gained in these trials was then used in a reaction optimisation for the formation of carvone semicarbazone. The production of high resolution surface channels (100-500 μm) means that these devices were capable of handling a wide range of concentrations (9 μM-38 mM), and are ideally suited to both analyte detection and process optimisation. This ability to tailor the chip design and its integrated features as a direct result of the reaction being assessed, at such a low time and cost penalty greatly increases the user's ability to optimise both their device and reaction. As a result of the information gained in this investigation, we are able to report the first instance of a 3D-printed LOC device with fully integrated, in-line monitoring capabilities
via
the use of embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro channels.
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via
stereolithography (SL) in a matter of hours. The spectroscopic performance of a variety of optical fibre combinations were tested, and the optimum path length for performing Ultraviolet-visible (UV-vis) spectroscopy determined. The information gained in these trials was then used in a reaction optimisation for the formation of carvone semicarbazone. The production of high resolution surface channels (100-500 μm) means that these devices were capable of handling a wide range of concentrations (9 μM-38 mM), and are ideally suited to both analyte detection and process optimisation. This ability to tailor the chip design and its integrated features as a direct result of the reaction being assessed, at such a low time and cost penalty greatly increases the user's ability to optimise both their device and reaction. As a result of the information gained in this investigation, we are able to report the first instance of a 3D-printed LOC device with fully integrated, in-line monitoring capabilities
via
the use of embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro channels.
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via
stereolithography (SL) in a matter of hours. The spectroscopic performance of a variety of optical fibre combinations were tested, and the optimum path length for performing Ultraviolet-visible (UV-vis) spectroscopy determined. The information gained in these trials was then used in a reaction optimisation for the formation of carvone semicarbazone. The production of high resolution surface channels (100-500 μm) means that these devices were capable of handling a wide range of concentrations (9 μM-38 mM), and are ideally suited to both analyte detection and process optimisation. This ability to tailor the chip design and its integrated features as a direct result of the reaction being assessed, at such a low time and cost penalty greatly increases the user's ability to optimise both their device and reaction. As a result of the information gained in this investigation, we are able to report the first instance of a 3D-printed LOC device with fully integrated, in-line monitoring capabilities
via
the use of embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro channels.
3DP was used to produce a fluidic device with embedded optical fibres capable of performing UV-vis spectroscopy directly inside micro-channels.</abstract><cop>England</cop><pmid>27452498</pmid><doi>10.1039/c6lc00562d</doi><tpages>12</tpages><oa>free_for_read</oa></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 1473-0197 |
| ispartof | Lab on a chip, 2016-01, Vol.16 (17), p.3362-3373 |
| issn | 1473-0197 1473-0189 1473-0189 |
| language | eng |
| recordid | cdi_rsc_primary_c6lc00562d |
| source | Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection |
| subjects | 3D printing Channels Design analysis Devices Formations Optical fibers Optimization Spectroscopy |
| title | Customisable 3D printed microfluidics for integrated analysis and optimisation |
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