J Nanobiotechnol

2021

DOI: 10.1186/s12951-021-01111-z

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Quantitative assessment of AD markers using naked eyes: point-of-care testing with paper-based lateral flow immunoassay

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Abstract: Aβ42 is one of the most extensively studied blood and Cerebrospinal fluid (CSF) biomarkers for the diagnosis of symptomatic and prodromal Alzheimer’s disease (AD). Because of the heterogeneity and transient nature of Aβ42 oligomers (Aβ42Os), the development of technologies for dynamically detecting changes in the blood or CSF levels of Aβ42 monomers (Aβ42Ms) and Aβ42Os is essential for the accurate diagnosis of AD. The currently commonly used Aβ42 ELISA test kits usually mis-detected the elevated Aβ42Os, leadi… Show more

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Cited by 20 publications

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“…There was a good correlation (R 2 = 0.9796) between the T line signal intensity and the detection concentration within the concentration range of 0.18–1820 ng/mL ( Figure 7 c). Previous studies have reported that the Aβ42Os levels in the blood of AD patients range from 0.1 to 1 ng/mL, as detected by sandwich ELISA [ 31 ]. The sensitivity of the nanozyme-strip for Aβ42Os detection needs to be improved.…”

Section: Resultsmentioning

confidence: 99%

An In Situ Study on Nanozyme Performance to Optimize Nanozyme-Strip for Aβ Detection

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et al. 2023

Self Cite

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The nanozyme-strip is a novel POCT technology which is different from the conventional colloidal gold strip. It primarily utilizes the catalytic activity of nanozyme to achieve a high-sensitivity detection of target by amplifying the detection signal. However, previous research has chiefly focused on optimizing nanozyme-strip from the perspective of increasing nanozyme activity, little is known about other physicochemical factors. In this work, three sizes of Fe3O4 nanozyme and three sizes of CoFe2O4 nanozyme were used to investigate the key factors of nanozyme-strip for optimizing and improving its detection performance. We found that three sizes of Fe3O4 nanozyme all gather at the bottom of the nitrocellulose (NC) membrane, and three sizes of CoFe2O4 nanozyme migrate smoothly on the NC membrane, respectively. After color development, the surface of NC membranes distributed with CoFe2O4 peroxidase nanozymes had significant color change. Experimental results show that CoFe2O4 nanozymes had better dispersity than Fe3O4 nanozymes in an aqueous solution. We observed that CoFe2O4 nanozymes with smaller particle size migrated to the middle of the NC membrane with a higher number of particles. According to the results above, 55 ± 6 nm CoFe2O4 nanozyme was selected to prepare the nanozyme probe and achieved a highly sensitive detection of Aβ42Os on the nanozyme-strip. These results suggest that nanozyme should be comprehensively evaluated in its dispersity, the migration on NC membrane, and the peroxidase-like activity to determine whether it can be applied to nanozyme-strip.

“…There was a good correlation (R 2 = 0.9796) between the T line signal intensity and the detection concentration within the concentration range of 0.18–1820 ng/mL ( Figure 7 c). Previous studies have reported that the Aβ42Os levels in the blood of AD patients range from 0.1 to 1 ng/mL, as detected by sandwich ELISA [ 31 ]. The sensitivity of the nanozyme-strip for Aβ42Os detection needs to be improved.…”

Section: Resultsmentioning

confidence: 99%

An In Situ Study on Nanozyme Performance to Optimize Nanozyme-Strip for Aβ Detection

¹

,

²

,

³

et al. 2023

Self Cite

View full text Add to dashboard Cite

The nanozyme-strip is a novel POCT technology which is different from the conventional colloidal gold strip. It primarily utilizes the catalytic activity of nanozyme to achieve a high-sensitivity detection of target by amplifying the detection signal. However, previous research has chiefly focused on optimizing nanozyme-strip from the perspective of increasing nanozyme activity, little is known about other physicochemical factors. In this work, three sizes of Fe3O4 nanozyme and three sizes of CoFe2O4 nanozyme were used to investigate the key factors of nanozyme-strip for optimizing and improving its detection performance. We found that three sizes of Fe3O4 nanozyme all gather at the bottom of the nitrocellulose (NC) membrane, and three sizes of CoFe2O4 nanozyme migrate smoothly on the NC membrane, respectively. After color development, the surface of NC membranes distributed with CoFe2O4 peroxidase nanozymes had significant color change. Experimental results show that CoFe2O4 nanozymes had better dispersity than Fe3O4 nanozymes in an aqueous solution. We observed that CoFe2O4 nanozymes with smaller particle size migrated to the middle of the NC membrane with a higher number of particles. According to the results above, 55 ± 6 nm CoFe2O4 nanozyme was selected to prepare the nanozyme probe and achieved a highly sensitive detection of Aβ42Os on the nanozyme-strip. These results suggest that nanozyme should be comprehensively evaluated in its dispersity, the migration on NC membrane, and the peroxidase-like activity to determine whether it can be applied to nanozyme-strip.

“…The first LFA, similar to those available today, was developed in the 1980s to detect the presence of human chorionic gonadotropin (hCG) in urine to confirm pregnancy . Since then, lateral flow tests have become successful analytical devices for PoC testing in various settings, ranging from detecting disease biomarkers, , pathogenic bacteria, viruses, and mycotoxins to chemical contaminants like veterinary drug residues or pesticides . Since the SARS-CoV-2 outbreak in 2019, LFAs have become one of the most abundant diagnostic tools for identification and monitoring of virus spread, needed to implement quarantine measures, despite their analytical drawbacks .…”

Section: Introductionmentioning

confidence: 99%

Development of a Paper-based Hematocrit Test and a Lateral Flow Assay to Detect Critical Fibrinogen Concentrations Using a Bottom-Up Pyramid Workflow Approach

Schobesberger,

Thumfart,

Selinger

et al. 2024

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Fibrinogen is a coagulation factor in human blood and the first one to reach critical levels in major bleeding. Hypofibrinogenemia (a too low fibrinogen concentration in blood) poses great challenges to first responders, clinicians, and healthcare providers since it represents a risk factor for exsanguination and massive transfusion requirements. Thus, the rapid assessment of the fibrinogen concentration at the point of care has gained considerable importance in preventing and managing major blood loss. However, in whole blood measurements, hematocrit variations affect the amount (volume fraction) of plasma that passes the detection zone. In an attempt to accurately determine realistic critical levels of fibrinogen (<1.5 mg/mL) in patients needing immediate treatment and medical interventions, we have developed novel diagnostic systems capable of estimating hematocrit and critical fibrinogen concentrations. A lateral flow assay (LFA) for the detection of fibrinogen has been developed by establishing a workflow employing rapid characterization methods to streamline LFA development. The integration of two detection lines enables (i) the identification of fibrinogen (first line) present in the sample and (ii) the determination of the clinically critical fibrinogen concentrations below 1.5 mg/mL (second line). Furthermore, the paper-based separation of blood cells from plasma provides a semiquantitative estimate of the hematocrit by analyzing the fractions. Initial validation of the point-of-care (PoC) hematocrit test revealed good comparability to a standard laboratory method. The developed diagnostic systems have the ability to accelerate decision-making in cases with major bleeding.

“…Especially immunoassays, when performed at the point of care (POC), could enable timely testing when a low turnaround time of analysis is highly needed, e.g., in first-aid settings (ambulance, physician offices, pharmacies). POC immunoassays also have great potential to assess time-critical and labile biomarkers, which are prone to degradation after sample collection. , Various lab-on-chip-type immunoassays, e.g., based on centrifugal − or paper-based − microfluidics, were proposed to realize POC applications. In these approaches, analyte capturing is typically achieved using immobilized antibodies, e.g., in porous matrices or on bead surfaces .…”

Section: Introductionmentioning

confidence: 99%

Microfluidic Device for Patient-Centric Multiplexed Assays with Readout in Centralized Laboratories

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Patient-centric sampling strategies, where the patient performs self-sampling and ships the sample to a centralized laboratory for readout, are on the verge of widespread adaptation. However, the key to a successful patient-centric workflow is user-friendliness, with few noncritical user interactions, and simple, ideally biohazard-free shipment. Here, we present a capillary-driven microfluidic device designed to perform the critical biomarker capturing step of a multiplexed immunoassay at the time of sample collection. On-chip sample drying enables biohazard-free shipment and allows us to make use of advanced analytics of specialized laboratories that offer the needed analytical sensitivity, reliability, and affordability. Using C-Reactive Protein, MCP1, S100B, IGFBP1, and IL6 as model blood biomarkers, we demonstrate the multiplexing capability and applicability of the device to a patient-centric workflow. The presented quantification of a biomarker panel opens up new possibilities for e-doctor and e-health applications.

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