SERRS. in situ substrate formation and improved detection using microfluidics
SERRS. in situ substrate formation and improved detection using microfluidics
Surface-enhanced resonance Raman scattering (SERRS) of a model derivative of TNT was detected using a microflow cell designed within the framework of the lab-on-a-chip concept, using only the analyte and readily available reagents.
The SERRS substrate, silver colloid, was prepared in situ, on-chip, by borohydride reduction of silver nitrate. The silver colloid was imaged within the chip using a white light microscope in either transmission or, due to the high reflectivity of the colloid, reflection mode. A fine stream of colloid 30 µm in width was formed in a 250-µm-wide channel at the point where the colloid preparation reagents met.
The chip was designed to produce a concentrated stream of colloid within a laminar regime, such that particles did not readily disperse into the fluid. One result of this was to reduce the effective volume of analysis. Attempts to deliberately disrupt this stream with microstructured pillars, fabricated in the fluidic channels, were unsuccessful. The chip was also designed to have the appropriate dimensions for detection using a modern Raman microscope system, which collects scattering from a very small volume. A dye derived from TNT was used as a model analyte.
Quantitative behavior was obtained over 4 orders of magnitude with a detection limit of 10 fmol. This performance is between 1 and 2 orders of magnitude better than that achieved using a macroflow SERRS cell. The technique has the added advantage that both reagent consumption and effluent production are greatly reduced, leading to reduced operating costs and a decreased environmental impact.
1503-1508
Keir, Ruth
1989b78a-b817-4d87-9858-38da00128b31
Igata, Eishi
57f639af-8360-4459-b493-dfa7975252e8
Arundell, Martin
e24d3405-a436-4d65-a6e4-2939ede79678
Smith, W. Ewen
901914d8-89b8-4467-9f55-0f98d949344c
Graham, Duncan
7273386a-2036-4024-afec-fe590db517ca
McHugh, Callum
5c9588ee-08ae-4de0-958b-f5c31694d7f6
Cooper, Jonathan M.
c8f72162-161e-4187-a2a1-05ccbf03af5a
5 March 2002
Keir, Ruth
1989b78a-b817-4d87-9858-38da00128b31
Igata, Eishi
57f639af-8360-4459-b493-dfa7975252e8
Arundell, Martin
e24d3405-a436-4d65-a6e4-2939ede79678
Smith, W. Ewen
901914d8-89b8-4467-9f55-0f98d949344c
Graham, Duncan
7273386a-2036-4024-afec-fe590db517ca
McHugh, Callum
5c9588ee-08ae-4de0-958b-f5c31694d7f6
Cooper, Jonathan M.
c8f72162-161e-4187-a2a1-05ccbf03af5a
Keir, Ruth, Igata, Eishi, Arundell, Martin, Smith, W. Ewen, Graham, Duncan, McHugh, Callum and Cooper, Jonathan M.
(2002)
SERRS. in situ substrate formation and improved detection using microfluidics.
Analytical Chemistry, 74 (7), .
(doi:10.1021/ac015625+).
Abstract
Surface-enhanced resonance Raman scattering (SERRS) of a model derivative of TNT was detected using a microflow cell designed within the framework of the lab-on-a-chip concept, using only the analyte and readily available reagents.
The SERRS substrate, silver colloid, was prepared in situ, on-chip, by borohydride reduction of silver nitrate. The silver colloid was imaged within the chip using a white light microscope in either transmission or, due to the high reflectivity of the colloid, reflection mode. A fine stream of colloid 30 µm in width was formed in a 250-µm-wide channel at the point where the colloid preparation reagents met.
The chip was designed to produce a concentrated stream of colloid within a laminar regime, such that particles did not readily disperse into the fluid. One result of this was to reduce the effective volume of analysis. Attempts to deliberately disrupt this stream with microstructured pillars, fabricated in the fluidic channels, were unsuccessful. The chip was also designed to have the appropriate dimensions for detection using a modern Raman microscope system, which collects scattering from a very small volume. A dye derived from TNT was used as a model analyte.
Quantitative behavior was obtained over 4 orders of magnitude with a detection limit of 10 fmol. This performance is between 1 and 2 orders of magnitude better than that achieved using a macroflow SERRS cell. The technique has the added advantage that both reagent consumption and effluent production are greatly reduced, leading to reduced operating costs and a decreased environmental impact.
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Published date: 5 March 2002
Identifiers
Local EPrints ID: 155833
URI: http://eprints.soton.ac.uk/id/eprint/155833
ISSN: 0003-2700
PURE UUID: 4b80866d-487d-4db4-b8a6-66baa62ac1d1
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Date deposited: 08 Jul 2010 10:47
Last modified: 14 Mar 2024 01:40
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Contributors
Author:
Ruth Keir
Author:
Eishi Igata
Author:
W. Ewen Smith
Author:
Duncan Graham
Author:
Callum McHugh
Author:
Jonathan M. Cooper
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