Autonomous reagent-based microfluidic pH sensor platform
Autonomous reagent-based microfluidic pH sensor platform
A portable sensor has been developed for in situ measurements of pH within aqueous environments.
The sensor design incorporates microfluidic technology, allowing for the use of low volume of samples and reagents, and an integrated low cost detection system that uses a light emitting diode as light source and a photodiode as the detector. Different combination of dyes has been studied in order to allow for a broader pH detection range, than can be obtained using a single dye. The optimum pH range for this particular dye combination was found to be between pH 4 and pH 9.
The reagents developed for pH measurement were first tested using bench-top instrumentation and once optimised, the selected formulation was then implemented in the microfluidic system.
The prototype system has been characterised in terms of pH response, linear range, reproducibility and stability. Results obtained using the prototype system are in good agreement with those obtained using reference instrumentation, i.e. a glass electrode/pH meter and analysis via spectrophotometer based assays.
The reagent (mixture #3) is shown to be stable for over 8 months, which is important for long term deployments. A high reproducibility is reported with a global RSD of ?1.8% across measurements of 90 samples, i.e. with respect to concentrations reported by a calibrated pH meter.
A series of real water samples from multiple sources were also analysed using the portable sensor system, of which the global error found was 3.84% showing its feasibility for real-world applications.
Microfluidic system, pH sensor, Water analysis, Autonomous monitoring
369-376
Perez de Vargas Sansalvador, Isabel M.
4f55863c-9ff0-4d32-aa7e-44ccb15f9e3e
Fay, Cormac D.
1132f248-c682-4313-aa8a-65f69c812ed5
Cleary, John
dd8a31a6-18b1-45ef-b7ac-7ca1ef591b9c
Nightingale, Adrian M.
53522fca-6fee-49f2-a79e-4cfeaaa153f3
Mowlem, Matthew C.
6f633ca2-298f-48ee-a025-ce52dd62124f
Diamond, Dermot
fdee941a-bc0b-44ee-9155-7c5175e35b79
31 March 2016
Perez de Vargas Sansalvador, Isabel M.
4f55863c-9ff0-4d32-aa7e-44ccb15f9e3e
Fay, Cormac D.
1132f248-c682-4313-aa8a-65f69c812ed5
Cleary, John
dd8a31a6-18b1-45ef-b7ac-7ca1ef591b9c
Nightingale, Adrian M.
53522fca-6fee-49f2-a79e-4cfeaaa153f3
Mowlem, Matthew C.
6f633ca2-298f-48ee-a025-ce52dd62124f
Diamond, Dermot
fdee941a-bc0b-44ee-9155-7c5175e35b79
Perez de Vargas Sansalvador, Isabel M., Fay, Cormac D., Cleary, John, Nightingale, Adrian M., Mowlem, Matthew C. and Diamond, Dermot
(2016)
Autonomous reagent-based microfluidic pH sensor platform.
Sensors and Actuators B: Chemical, 225, .
(doi:10.1016/j.snb.2015.11.057).
Abstract
A portable sensor has been developed for in situ measurements of pH within aqueous environments.
The sensor design incorporates microfluidic technology, allowing for the use of low volume of samples and reagents, and an integrated low cost detection system that uses a light emitting diode as light source and a photodiode as the detector. Different combination of dyes has been studied in order to allow for a broader pH detection range, than can be obtained using a single dye. The optimum pH range for this particular dye combination was found to be between pH 4 and pH 9.
The reagents developed for pH measurement were first tested using bench-top instrumentation and once optimised, the selected formulation was then implemented in the microfluidic system.
The prototype system has been characterised in terms of pH response, linear range, reproducibility and stability. Results obtained using the prototype system are in good agreement with those obtained using reference instrumentation, i.e. a glass electrode/pH meter and analysis via spectrophotometer based assays.
The reagent (mixture #3) is shown to be stable for over 8 months, which is important for long term deployments. A high reproducibility is reported with a global RSD of ?1.8% across measurements of 90 samples, i.e. with respect to concentrations reported by a calibrated pH meter.
A series of real water samples from multiple sources were also analysed using the portable sensor system, of which the global error found was 3.84% showing its feasibility for real-world applications.
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More information
Published date: 31 March 2016
Keywords:
Microfluidic system, pH sensor, Water analysis, Autonomous monitoring
Organisations:
Ocean Technology and Engineering
Identifiers
Local EPrints ID: 386931
URI: http://eprints.soton.ac.uk/id/eprint/386931
ISSN: 0925-4005
PURE UUID: 936a3e6a-4784-44ae-b8f6-0b6a00c8def4
Catalogue record
Date deposited: 04 Feb 2016 14:04
Last modified: 15 Mar 2024 03:02
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Contributors
Author:
Isabel M. Perez de Vargas Sansalvador
Author:
Cormac D. Fay
Author:
John Cleary
Author:
Adrian M. Nightingale
Author:
Matthew C. Mowlem
Author:
Dermot Diamond
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