Wicking in Porous Polymeric Membranes: Determination of an Effective Capillary Radius to Predict the Flow Behavior in Lateral Flow Assays

Altschuh, Patrick; Kunz, Willfried; Bremerich, Marcel; Reiter, Andreas; Selzer, Michael; Nestler, Britta

doi:10.3390/membranes12070638

Cited by 7 publications

(4 citation statements)

References 52 publications

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“…Capillary rise time, a requirement set by the manufacturer for nitrocellulose membranes, is the period needed for a fluid front to pass through a membrane with a 40 mm width. The kinetics and rate of assay development are crucial, and the selected wicking rate will have a significant impact on the sensitivity and effectiveness of the test [ 64 , 65 ].…”

Section: Principle Of Lfamentioning

confidence: 99%

Lateral Flow Assay for Hepatitis B Detection: A Review of Current and New Assays

2023

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From acute to chronic hepatitis, cirrhosis, and hepatocellular cancer, hepatitis B infection causes a broad spectrum of liver diseases. Molecular and serological tests have been used to diagnose hepatitis B-related illnesses. Due to technology limitations, it is challenging to identify hepatitis B infection cases at an early stage, particularly in a low- and middle-income country with constrained resources. Generally, the gold-standard methods to detect hepatitis B virus (HBV) infection requires dedicated personnel, bulky, expensive equipment and reagents, and long processing times which delay the diagnosis of HBV. Thus, lateral flow assay (LFA), which is inexpensive, straightforward, portable, and operates reliably, has dominated point-of-care diagnostics. LFA consists of four parts: a sample pad where samples are dropped; a conjugate pad where labeled tags and biomarker components are combined; a nitrocellulose membrane with test and control lines for target DNA-probe DNA hybridization or antigen-antibody interaction; and a wicking pad where waste is stored. By modifying the pre-treatment during the sample preparation process or enhancing the signal of the biomarker probes on the membrane pad, the accuracy of the LFA for qualitative and quantitative analysis can be improved. In this review, we assembled the most recent developments in LFA technologies for the progress of hepatitis B infection detection. Prospects for ongoing development in this area are also covered.

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Section: Principle Of Lfamentioning

confidence: 99%

Lateral Flow Assay for Hepatitis B Detection: A Review of Current and New Assays

2023

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“…reported that 44 LFAs were authorized by the FDA in the USA for COVID-19 in vitro diagnostics. Simply, an LFA can be described as a system consisting of an analytical membrane that act as an autarkic microfluidic pump system capable of transporting the pretreated (if necessary) sample from the sample pad to conjugate pad [ 7 ]. While diffusing through the conjugate pad, the sample is mixed with gold nanoparticles (AuNPs), biomolecule conjugates, and additives, which react with the antibodies on the membrane [ 4 , 7 ] (Fig.…”

Section: Introductionmentioning

confidence: 99%

“…Lucas and Washburn derived a solution for porous mediums, considering the capillary pressure developed in a cylindrical capillary with the assumption that the porous medium is a collection of cylindrical capillaries [ 15 ]. Altschuh et al [ 7 ] demonstrated that the estimated effective pore radius is approximately eight to ten times higher than the geometric means. They argued that use of solutions such as the Young–Laplace equation and Lucas and Washburn solutions are not applicable in the context of membranes, as the structures are often non-axisymmetric and closed.…”

Section: Introductionmentioning

confidence: 99%

Predicting the wicking rate of nitrocellulose membranes from recipe data: a case study using ANN at a membrane manufacturing in South Korea

Dissanayake,

Kang,

Park

et al. 2024

ANAL. SCI.

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Lateral flow assays have been widely used for detecting coronavirus disease 2019 (COVID-19). A lateral flow assay consists of a Nitrocellulose (NC) membrane, which must have a specific lateral flow rate for the proteins to react. The wicking rate is conventionally used as a method to assess the lateral flow in membranes. We used multiple regression and artificial neural networks (ANN) to predict the wicking rate of NC membranes based on membrane recipe data. The developed ANN predicted the wicking rate with a mean square error of 0.059, whereas the multiple regression had a square error of 0.503. This research also highlighted the significant impact of the water content on the wicking rate through images obtained from scanning electron microscopy. The findings of this research can cut down the research and development costs of novel NC membranes with a specific wicking rate significantly, as the algorithm can predict the wicking rate based on the membrane recipe. Graphical abstract Correlation matrix displaying the distribution of the variables and linear correlations

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“…However, real microstructures do not always ensure periodicity, except for few cases, such as crystal structures. In particular, when extracting a representative element from reference experimental data [3][4][5], such as computer tomography images, the representative volume element is typically cropped from a larger network. This cropping process often results in the truncation of boundaries, introducing non-periodic features into the extracted element.…”

Section: Introductionmentioning

confidence: 99%

A U-Net-based self-stitching method for generating periodic grain structures

Ji,

Koeppe,

Altschuh

et al. 2024

Phys. Scr.

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When modeling microstructures, the computational resource requirements increase rapidly as the simulation domain becomes larger. As a result, simulating a small representative fraction under periodic boundary conditions is often a necessary simplification. However, the truncated structures leave nonphysical boundaries, which are detrimental to numerical modeling. Here, we propose a self-stitching algorithm for generating periodic structures, demonstrated in a grain structure. The main idea of our algorithm is to artificially add structural information between mismatched boundary pairs, using the hierarchical spatial predictions of the U-Net. The model is trained with 20,000 grain sample pairs simulated from multiphase field simulations, resulting in the successful generation of periodic grain structures as expected. Furthermore, we employ an energy-based metric, the local curvature, to highlight the quality of the generated samples. Through this metric, we determine that the optimum value of the width of the mask is 1/16 of the sample width. The algorithm provides an automatic and unbiased way to obtain periodic boundaries in grain structures and can be applied to porous microstructures in a similar way.

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Wicking in Porous Polymeric Membranes: Determination of an Effective Capillary Radius to Predict the Flow Behavior in Lateral Flow Assays

Cited by 7 publications

References 52 publications

Lateral Flow Assay for Hepatitis B Detection: A Review of Current and New Assays

Lateral Flow Assay for Hepatitis B Detection: A Review of Current and New Assays

Predicting the wicking rate of nitrocellulose membranes from recipe data: a case study using ANN at a membrane manufacturing in South Korea

A U-Net-based self-stitching method for generating periodic grain structures

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