Novel functionalities of hybrid paper-polymer centrifugal devices for assay performance enhancement

Wiederoder, Michael S.; Smith, Suzanne; Madzivhandila, Phophi; Mager, Dario; Moodley, K; DeVoe, Don L.; Land, Kevin

doi:10.1063/1.5002644

Cited by 14 publications

(10 citation statements)

References 42 publications

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“…Consecuently, to include sample preconcentration steps prior to analysis is necessary [23]. Different preconcentration methods based on immunomagnetic separation (IMS) systems [24][25][26][27], centrifugation [28,29] and membrane filtration have been coupled to sensing methods. Nevertheless, membrane filtration is considered the first choice for large sample volumes (≥10 mL) [30,31].…”

Section: Introductionmentioning

confidence: 99%

Rapid Detection of Legionella pneumophila in Drinking Water, Based on Filter Immunoassay and Chronoamperometric Measurement

et al. 2020

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Legionella is a pathogenic bacterium, ubiquitous in freshwater environments and able to colonise man-made water systems from which it can be transmitted to humans during outbreaks. The prevention of such outbreaks requires a fast, low cost, automated and often portable detection system. In this work, we present a combination of sample concentration, immunoassay detection, and measurement by chronoamperometry. A nitrocellulose microfiltration membrane is used as support for both the water sample concentration and the Legionella immunodetection. The horseradish peroxidase enzymatic label of the antibodies permits using the redox substrate 3,3′,5,5′-Tetramethylbenzidine to generate current changes proportional to the bacterial concentration present in drinking water. Carbon screen-printed electrodes are employed in the chronoamperometric measurements. Our system reduces the detection time: from the 10 days required by the conventional culture-based methods, to 2–3 h, which could be crucial to avoid outbreaks. Additionally, the system shows a linear response (R2 value of 0.99), being able to detect a range of Legionella concentrations between 101 and 104 cfu·mL−1 with a detection limit (LoD) of 4 cfu·mL−1.

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Section: Introductionmentioning

confidence: 99%

Rapid Detection of Legionella pneumophila in Drinking Water, Based on Filter Immunoassay and Chronoamperometric Measurement

et al. 2020

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“…Prediction and control over Q can be a key aspect in proper microdevice functioning as well as assay performance. [35][36][37] Notably, variations on this equation ‡ can account for the specific cross-sectional geometry of individual channel structures. 38 Centrifugal flow within porous substrates Unlike the initial attempts at microdevice fabrication in the 1980-90's, glass and silicon have been largely superseded by plastics.…”

Section: Centrifugal Microdevice Fluid Dynamicsmentioning

confidence: 99%

Integrated membranes within centrifugal microfluidic devices: a review

O'Connell

Landers

2023

Lab Chip

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“…It does not require a complex pumping system but rather a simple motor and no external instrumentation. Wiederoder et al 20 proposed a hyper polymer-paper centrifugal device for sample enrichment, mixing, and integration of sequential assay steps using E. coli bacteria. Another interesting approach by Chen et al 21 is based on centrifugal microflows driven by ionic wind generated near the tip of a corona needle held above a small reservoir.…”

Section: Introductionmentioning

confidence: 99%

A nanofilter for fluidic devices by pillar-assisted self-assembly microparticles

2018

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We present a nanofilter based on pillar-assisted self-assembly microparticles for efficient capture of bacteria. Under an optimized condition, we simply fill the arrays of microscale pillars with submicron scale polystyrene particles to create a filter with nanoscale pore diameter in the range of 308 nm. The design parameters such as the pillar diameter and the inter-pillar spacing in the range of 5 μm-40 μm are optimized using a multi-physics finite element analysis and computational study based on bi-directionally coupled laminar flow and particle tracking solvers. The underlying dynamics of microparticles accumulation in the pillar array region are thoroughly investigated by studying the pillar wall shear stress and the filter pore diameter. The impact of design parameters on the device characteristics such as microparticles entrapment efficiency, pressure drop, and inter-pillar flow velocity is studied. We confirm a bell-curve trend in the capture efficiency versus inter-pillar spacing. Accordingly, the 10 μm inter-pillar spacing offers the highest capture capability (58.8%), with a decreasing entrapping trend for devices with larger inter-pillar spacing. This is the case that the 5 μm inter-pillar spacing demonstrates the highest pillar wall shear stress limiting its entrapping efficiency. As a proof of concept, fluorescently labeled Escherichia coli bacteria (E. coli) were captured using the proposed device. This device provides a simple design, robust operation, and ease of use. All of which are essential attributes for point of care devices.

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Novel functionalities of hybrid paper-polymer centrifugal devices for assay performance enhancement

Cited by 14 publications

References 42 publications

Rapid Detection of Legionella pneumophila in Drinking Water, Based on Filter Immunoassay and Chronoamperometric Measurement

Rapid Detection of Legionella pneumophila in Drinking Water, Based on Filter Immunoassay and Chronoamperometric Measurement

Integrated membranes within centrifugal microfluidic devices: a review

A nanofilter for fluidic devices by pillar-assisted self-assembly microparticles

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