Covalent immobilisation of antibodies in Teflon-FEP microfluidic devices for the sensitive quantification of clinically relevant protein biomarkers

Pivetal, Jérémy; Pereira, Filipa; Barbosa, Ana I.; Castanheira, Ana P.; Reis, Nuno M.; Edwards, Alexander D.

doi:10.1039/c6an02622b

Cited by 32 publications

(32 citation statements)

References 35 publications

(57 reference statements)

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“…In contrast, fluoropolymer microcapillaries (FEP) have been coated with reagents to achieve hydrophilic surface inside the capillaries which can load aqueous samples rapidly ( Figure 2 h) [ 16 , 42 , 43 , 44 , 45 ]. Pivetal et al [ 42 ] converted the surface of FEP microcapillaries by coating with a layer of polyvinyl alcohol (PVA) and cross-linked reagents for analyte detections (colorimetric or fluorescent), such as the detection of prostate-specific antigen (PSA) [ 43 , 44 ] and cytokines [ 45 ]. These FEP capillaries were injected with multiple solutions, such as PSA standard, detection antibodies, enzyme complex, washing solutions and enzymatic substrates, which were injected in all channels simultaneously.…”

Section: Recent Advances In Capillary-driven Flow Microfluidicsmentioning

confidence: 99%

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

et al. 2020

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Point-of-care (POC) or near-patient testing allows clinicians to accurately achieve real-time diagnostic results performed at or near to the patient site. The outlook of POC devices is to provide quicker analyses that can lead to well-informed clinical decisions and hence improve the health of patients at the point-of-need. Microfluidics plays an important role in the development of POC devices. However, requirements of handling expertise, pumping systems and complex fluidic controls make the technology unaffordable to the current healthcare systems in the world. In recent years, capillary-driven flow microfluidics has emerged as an attractive microfluidic-based technology to overcome these limitations by offering robust, cost-effective and simple-to-operate devices. The internal wall of the microchannels can be pre-coated with reagents, and by merely dipping the device into the patient sample, the sample can be loaded into the microchannel driven by capillary forces and can be detected via handheld or smartphone-based detectors. The capabilities of capillary-driven flow devices have not been fully exploited in developing POC diagnostics, especially for antimicrobial resistance studies in clinical settings. The purpose of this review is to open up this field of microfluidics to the ever-expanding microfluidic-based scientific community.

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Section: Recent Advances In Capillary-driven Flow Microfluidicsmentioning

confidence: 99%

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

et al. 2020

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“…This material comprises a plastic ribbon containing an array of 10 capillaries along its length with an average diameter of 206 ± 12.6µm and external dimensions of 4.5 ± 0.10 mm wide by 0.6 ± 0.05 mm thick. This material was coated to make internally hydrophilic for production of dipstick microfluidic devices by incubation with a 5 mg/mL solution of PVOH in water (MW 146,000-186,000, >99% hydrolysed, Sigma-Aldrich, UK) at room temperature for a minimum of 2h (26). The material was then washed manually to remove crosslinker with 5 ml of PBS with 0.5 % Tween 20 (Sigma-Aldrich, UK) solution to remove uncoated PVOH, and dried with multiple changes of air using a 50 mL syringe.…”

Section: Production Of Antimicrobial Susceptibility Dipstick Devicesmentioning

confidence: 99%

“…Firstly, even faster detection of growth is needed, with colorimetric resazurin detection known to be hard to colorimetrically quantify by digital imaging due to complex changes in visible light absorbance (27). Faster detection may be achieved by switching to fluorimetric growth detection, previously used by our group for immunoassays in MCF (26). Secondly, a better understanding of the predictive value of direct urine AST testing (without overnight plating and colony isolation) in clinical samples is vital.…”

Section: Feasibility Of Direct Ast In Clinical Urine Samplesmentioning

confidence: 99%

High Dynamic Range Bacterial Cell Detection in a Novel “Lab-In-A-Comb” for High-Throughput Antibiotic Susceptibility Testing of Clinical Urine Samples

Pivetal

Woodward

Reis

et al. 2017

Preprint

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Antibiotic resistance in urinary tract infection is a major global challenge, and improved costeffective and rapid antibiotic susceptibility tests (AST) are urgently needed to inform correct antibiotic selection. Although microfluidic technology can miniaturise AST, the high dynamic range of pathogen density found in clinical urine samples makes direct testing of clinical samples -rather than testing colonies from overnight agar plates -extremely challenging. We evaluated for the first time how pathogen concentration in urine affects microfluidic AST using a novel microplatecompatible high-throughput microfluidic AST system termed "Lab-on-a-Comb". When tested with clinical E. coli isolates at standardised density, these devices gave identical antibiotic susceptibility profiles to standard disc diffusion and microtitre plate tests. Bacterial detection directly in synthetic urine spiked with clinical E. coli UTI isolates was possible over a very large dynamic range of starting cell densities, from 10 3 -10 8 CFU/mL which covers the range of pathogen cell densities found in patient urine. The lowest cell density where cell growth was reproducibly detected optically was 9.6x10 2 CFU/mL, corresponding to one single CFU detected in a 1 L microcapillary-an unprecedented level of sensitivity. Cell growth kinetics followed a simple Monod model with fast growth limited by the substrate availability and an estimated doubling time of 24.5 min, indicating optimal E. coli growth conditions within these microfluidic devices. There was a trade-off between sensitivity and speed of detection, with 10 5

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“…Glass/hydrophilic capillaries have also been used to drive flow via capillary action, as described by Lapierre et al [17], who used bare glass capillaries to collect blood samples. In contrast, fluoropolymer microcapillaries (FEP) have been coated with reagents to render their surface hydrophilic and draw up blood or aqueous samples in a minute fraction of time [18][19][20][21][22]. Pivetal et al [19] coated FEP capillaries with polyvinyl alcohol (PVA) to convert their surface from hydrophobic to hydrophilic and attached reagents or antibodies on the surface for the detection of protein biomarkers.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast, fluoropolymer microcapillaries (FEP) have been coated with reagents to render their surface hydrophilic and draw up blood or aqueous samples in a minute fraction of time [18][19][20][21][22]. Pivetal et al [19] coated FEP capillaries with polyvinyl alcohol (PVA) to convert their surface from hydrophobic to hydrophilic and attached reagents or antibodies on the surface for the detection of protein biomarkers. The reagents reacted with the biomarkers, generating a colour or fluorescent signals which were detected under a microscope attached to a camera.…”

Section: Introductionmentioning

confidence: 99%

Design and Fabrication of Capillary-Driven Flow Device for Point-Of-Care Diagnostics

Hassan

Zhang

2020

Biosensors

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Point-of-care (POC) diagnostics enables the diagnosis and monitoring of patients from the clinic or their home. Ideally, POC devices should be compact, portable and operatable without the requirement of expertise or complex fluid mechanical controls. This paper showcases a chip-and-dip device, which works on the principle of capillary-driven flow microfluidics and allows analytes' detection by multiple microchannels in a single microchip via smartphone imaging. The chip-and-dip device, fabricated with inexpensive materials, works by simply dipping the reagents-coated microchip consisting of microchannels into a fluidic sample. The sample is loaded into the microchannels via capillary action and reacts with the reagents to produce a colourimetric signal. Unlike dipstick tests, this device allows the loading of bacterial/pathogenic samples for antimicrobial testing. A single device can be coated with multiple reagents, and more analytes can be detected in one sample. This platform could be used for a wide variety of assays. Here, we show the design, fabrication and working principle of the chip-and-dip flow device along with a specific application consisting in the determination of β-lactamase activity and cortisol. The simplicity, robustness and multiplexing capability of the chip-and-dip device will allow it to be used for POC diagnostics.

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Covalent immobilisation of antibodies in Teflon-FEP microfluidic devices for the sensitive quantification of clinically relevant protein biomarkers

Cited by 32 publications

References 35 publications

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

Capillary-Driven Flow Microfluidics Combined with Smartphone Detection: An Emerging Tool for Point-of-Care Diagnostics

High Dynamic Range Bacterial Cell Detection in a Novel “Lab-In-A-Comb” for High-Throughput Antibiotic Susceptibility Testing of Clinical Urine Samples

Design and Fabrication of Capillary-Driven Flow Device for Point-Of-Care Diagnostics

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