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Antibody surface coverage drives matrix interference in microfluidic capillary immunoassays

Antibody surface coverage drives matrix interference in microfluidic capillary immunoassays
Antibody surface coverage drives matrix interference in microfluidic capillary immunoassays
The performance of biosensors is often optimized in buffers, which brings inconsistencies during applications with biological samples. Current strategies for minimizing sample (matrix) interference are complex to automate and miniaturize, involving, e.g., sample dilution or recovery of serum/plasma. This study shows the first systematic analysis using hundreds of actual microfluidic immunoassay fluoropolymer strips to understand matrix interference in microflow systems. As many interfering factors are assay-specific, we have explored matrix interference for a range of enzymatic immunoassays, including a direct mIgG/anti-mIgG, a sandwich cancer biomarker PSA, and a sandwich inflammatory cytokine IL-1β. Serum matrix interference was significantly affected by capillary antibody surface coverage, suggesting for the first time that the main cause of the serum matrix effect is low-affinity serum components (e.g., autoantibodies) competing with high-affinity antigens for the immobilized antibody. Additional experiments carried out with different capillary diameters confirmed the importance of antibody surface coverage in managing matrix interference. Building on these findings, we propose a novel analytical approach where antibody surface coverage and sample incubation times are key for eliminating and/or minimizing serum matrix interference, consisting in bioassay optimization carried out in serum instead of buffer, without compromising the performance of the bioassay or adding extra cost or steps. This will help establishing a new route toward faster development of modern point-of-care tests and effective biosensor development.
2379-3694
2682–2690
Barbosa, Ana I.
5b4f3ab6-637f-4951-bea1-931d11f602ab
Edwards, Alexander D.
bc3d9b93-a533-4144-937b-c673d0a28879
Reis, Nuno M.
898670e7-a794-4302-81ce-03a4d86cc17a
Barbosa, Ana I.
5b4f3ab6-637f-4951-bea1-931d11f602ab
Edwards, Alexander D.
bc3d9b93-a533-4144-937b-c673d0a28879
Reis, Nuno M.
898670e7-a794-4302-81ce-03a4d86cc17a

Barbosa, Ana I., Edwards, Alexander D. and Reis, Nuno M. (2021) Antibody surface coverage drives matrix interference in microfluidic capillary immunoassays. ACS Sensors, 6 (7), 2682–2690. (doi:10.1021/acssensors.1c00704).

Record type: Article

Abstract

The performance of biosensors is often optimized in buffers, which brings inconsistencies during applications with biological samples. Current strategies for minimizing sample (matrix) interference are complex to automate and miniaturize, involving, e.g., sample dilution or recovery of serum/plasma. This study shows the first systematic analysis using hundreds of actual microfluidic immunoassay fluoropolymer strips to understand matrix interference in microflow systems. As many interfering factors are assay-specific, we have explored matrix interference for a range of enzymatic immunoassays, including a direct mIgG/anti-mIgG, a sandwich cancer biomarker PSA, and a sandwich inflammatory cytokine IL-1β. Serum matrix interference was significantly affected by capillary antibody surface coverage, suggesting for the first time that the main cause of the serum matrix effect is low-affinity serum components (e.g., autoantibodies) competing with high-affinity antigens for the immobilized antibody. Additional experiments carried out with different capillary diameters confirmed the importance of antibody surface coverage in managing matrix interference. Building on these findings, we propose a novel analytical approach where antibody surface coverage and sample incubation times are key for eliminating and/or minimizing serum matrix interference, consisting in bioassay optimization carried out in serum instead of buffer, without compromising the performance of the bioassay or adding extra cost or steps. This will help establishing a new route toward faster development of modern point-of-care tests and effective biosensor development.

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barbosa-et-al-2021-antibody-surface-coverage-drives-matrix-interference-in-microfluidic-capillary-immunoassays - Version of Record
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More information

Accepted/In Press date: 7 June 2021
Published date: 17 July 2021
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Identifiers

Local EPrints ID: 495108
URI: http://eprints.soton.ac.uk/id/eprint/495108
DOI: doi:10.1021/acssensors.1c00704
ISSN: 2379-3694
PURE UUID: e082f8b1-0b7b-4369-afb3-350e2d2aa9e8
ORCID for Alexander D. Edwards: ORCID iD orcid.org/0000-0003-2369-989X

Catalogue record

Date deposited: 29 Oct 2024 17:43
Last modified: 02 Nov 2024 03:09

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Contributors

Author: Ana I. Barbosa
Author: Alexander D. Edwards ORCID iD
Author: Nuno M. Reis

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