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Gravity-driven microfluidic siphons: fluidic characterization and application to quantitative immunoassays

Gravity-driven microfluidic siphons: fluidic characterization and application to quantitative immunoassays
Gravity-driven microfluidic siphons: fluidic characterization and application to quantitative immunoassays
A range of biosensing techniques including immunoassays are routinely used for quantitation of analytes in biological samples and available in a range of formats, from centralized lab testing (e.g., microplate enzyme-linked immunosorbent assay (ELISA)) to automated point-of-care (POC) and lateral flow immunochromatographic tests. High analytical performance is intrinsically linked to the use of a sequence of reagent and washing steps, yet this is extremely challenging to deliver at the POC without a high level of fluidic control involving, e.g., automation, fluidic pumping, or manual fluid handling/pipetting. Here we introduce a microfluidic siphon concept that conceptualizes a multistep ″dipstick″ for quantitative, enzymatically amplified immunoassays using a strip of microporous or microbored material. We demonstrated that gravity-driven siphon flow can be realized in single-bore glass capillaries, a multibored microcapillary film, and a glass fiber porous membrane. In contrast to other POC devices proposed to date, the operation of the siphon is only dependent on the hydrostatic liquid pressure (gravity) and not capillary forces, and the unique stepwise approach to the delivery of the sample and immunoassay reagents results in zero dead volume in the device, no reagent overlap or carryover, and full start/stop fluid control. We demonstrated applications of a 10-bore microfluidic siphon as a portable ELISA system without compromised quantitative capabilities in two global diagnostic applications: (1) a four-plex sandwich ELISA for rapid smartphone dengue serotype identification by serotype-specific dengue virus NS1 antigen detection, relevant for acute dengue fever diagnosis, and (2) quantitation of anti-SARS-CoV-2 IgG and IgM titers in spiked serum samples. Diagnostic siphons provide the opportunity for high-performance immunoassay testing outside sophisticated laboratories, meeting the rapidly changing global clinical and public health needs.
2379-3694
Reis, N.M.
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Needs, Sarah Helen
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Jegouic, S.M.
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Gill, K.K.
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Sirivisoot, S.
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Howard, S.
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Kempe, J.
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Bola, S.
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Al-Hakeem, K.
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Jones, I.M.
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Prommool, T.
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Luangaram, P.
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Avirutnan, P.
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Puttikhunt, C.
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Edwards, A.D.
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Reis, N.M.
898670e7-a794-4302-81ce-03a4d86cc17a
Needs, Sarah Helen
24425556-99e3-4c46-995b-2381776a0a38
Jegouic, S.M.
a4c352df-3861-400f-a288-1cc19769e10d
Gill, K.K.
cc6167fc-3e84-4031-ae65-937c5918455d
Sirivisoot, S.
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Howard, S.
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Kempe, J.
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Bola, S.
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Al-Hakeem, K.
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Jones, I.M.
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Prommool, T.
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Luangaram, P.
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Avirutnan, P.
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Puttikhunt, C.
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Edwards, A.D.
bc3d9b93-a533-4144-937b-c673d0a28879

Reis, N.M., Needs, Sarah Helen, Jegouic, S.M., Gill, K.K., Sirivisoot, S., Howard, S., Kempe, J., Bola, S., Al-Hakeem, K., Jones, I.M., Prommool, T., Luangaram, P., Avirutnan, P., Puttikhunt, C. and Edwards, A.D. (2021) Gravity-driven microfluidic siphons: fluidic characterization and application to quantitative immunoassays. ACS Sensors, 6 (12). (doi:10.1021/acssensors.1c01524).

Record type: Article

Abstract

A range of biosensing techniques including immunoassays are routinely used for quantitation of analytes in biological samples and available in a range of formats, from centralized lab testing (e.g., microplate enzyme-linked immunosorbent assay (ELISA)) to automated point-of-care (POC) and lateral flow immunochromatographic tests. High analytical performance is intrinsically linked to the use of a sequence of reagent and washing steps, yet this is extremely challenging to deliver at the POC without a high level of fluidic control involving, e.g., automation, fluidic pumping, or manual fluid handling/pipetting. Here we introduce a microfluidic siphon concept that conceptualizes a multistep ″dipstick″ for quantitative, enzymatically amplified immunoassays using a strip of microporous or microbored material. We demonstrated that gravity-driven siphon flow can be realized in single-bore glass capillaries, a multibored microcapillary film, and a glass fiber porous membrane. In contrast to other POC devices proposed to date, the operation of the siphon is only dependent on the hydrostatic liquid pressure (gravity) and not capillary forces, and the unique stepwise approach to the delivery of the sample and immunoassay reagents results in zero dead volume in the device, no reagent overlap or carryover, and full start/stop fluid control. We demonstrated applications of a 10-bore microfluidic siphon as a portable ELISA system without compromised quantitative capabilities in two global diagnostic applications: (1) a four-plex sandwich ELISA for rapid smartphone dengue serotype identification by serotype-specific dengue virus NS1 antigen detection, relevant for acute dengue fever diagnosis, and (2) quantitation of anti-SARS-CoV-2 IgG and IgM titers in spiked serum samples. Diagnostic siphons provide the opportunity for high-performance immunoassay testing outside sophisticated laboratories, meeting the rapidly changing global clinical and public health needs.

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Published date: 2 December 2021
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Identifiers

Local EPrints ID: 502234
URI: http://eprints.soton.ac.uk/id/eprint/502234
DOI: doi:10.1021/acssensors.1c01524
ISSN: 2379-3694
PURE UUID: 8e2a22fc-5e9b-4f10-a61f-bc77c9080f97
ORCID for A.D. Edwards: ORCID iD orcid.org/0000-0003-2369-989X

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Date deposited: 18 Jun 2025 16:46
Last modified: 21 Jun 2025 02:21

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Contributors

Author: N.M. Reis
Author: Sarah Helen Needs
Author: S.M. Jegouic
Author: K.K. Gill
Author: S. Sirivisoot
Author: S. Howard
Author: J. Kempe
Author: S. Bola
Author: K. Al-Hakeem
Author: I.M. Jones
Author: T. Prommool
Author: P. Luangaram
Author: P. Avirutnan
Author: C. Puttikhunt
Author: A.D. Edwards ORCID iD

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