biotinylated anti ifabp detection antibody (R&D Systems)
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Biotinylated Anti Ifabp Detection Antibody, supplied by R&D Systems, used in various techniques. Bioz Stars score: 94/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/biotinylated+anti+ifabp+detection+antibody/pmc13114182-44-7-19?v=R%26D+Systems
Average 94 stars, based on 1 article reviews
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1) Product Images from "Nanocomposite-Based Dual Electrochemical Immunosensor for Simultaneous Detection of Intestinal Barrier Biomarkers: Intestinal Fatty Acid Binding Protein and Fecal Calprotectin"
Article Title: Nanocomposite-Based Dual Electrochemical Immunosensor for Simultaneous Detection of Intestinal Barrier Biomarkers: Intestinal Fatty Acid Binding Protein and Fecal Calprotectin
Journal: Biosensors
doi: 10.3390/bios16040199
Figure Legend Snippet: Schematic illustration of the stepwise fabrication and operating principle of the electrochemical dual immunosensor for the simultaneous determination of iFABP and FC. The procedure includes (i) electrochemical grafting of p -aminobenzoic acid diazonium salt onto SPdCEs to introduce carboxylic groups, followed by EDC/sulfo-NHS activation; (ii) covalent immobilization of capture antibodies (anti-iFABP and anti-FC); (iii) surface blocking with BSA to minimize nonspecific adsorption; (iv) formation of the sandwich immunocomplex through antigen binding and subsequent incubation with biotinylated detection antibodies; and (v) signal amplification using the V 2 O 5 /MWCNTs-HRP–streptavidin nanocomposite via biotin–streptavidin interaction. The analytical signal is generated by the catalytic reduction in H 2 O 2 , combining the peroxidase-like activity of V 2 O 5 and the enzymatic activity of HRP, and recorded amperometrically for each biomarker.
Techniques Used: Introduce, Activation Assay, Blocking Assay, Adsorption, Binding Assay, Incubation, Amplification, Generated, Activity Assay, Biomarker Discovery
Figure Legend Snippet: Optimization of the different experimental variables involved in the preparation of the electrochemical immunosensor for iFABP. Dependence of the amperometric responses measured in the absence (light purple, N) or in the presence (dark purple, S) of 1 ng mL −1 iFABP standards and the resulting signal-to-blank ratio (red lines, S/N) with the following: anti-iFABP concentration and incubation time ( A , B ); BSA concentration and incubation time ( C , D ); incubation time for iFABP standard ( E ); concentration of Biotin-anti-iFABP and incubation time ( F , G ); dilution of nanocomposite V 2 O 5 /MWCNTs/HRP-Strep ( H ). Unless otherwise specified, the concentration of iFABP used in the time-dependent panels ( B , D , E , G ) was fixed at 1 ng mL −1 . The background signal (N) arises from the intrinsic electrochemical activity of the nanocomposite and nonspecific adsorption processes, as confirmed by control experiments in the absence of antigen. After each incubation step, electrodes were rinsed with PBS to remove unbound species and minimize nonspecific contributions. Incubation time = 20 min. Error bars estimated as triple of the standard deviation of three replicates.
Techniques Used: Concentration Assay, Incubation, Activity Assay, Adsorption, Control, Standard Deviation
Figure Legend Snippet: Cyclic voltammograms ( A , B ) and Nyquist plots ( C , D ) recorded for 5 mM Fe(CN) 6 3−/4− in 0.1 mol L −1 PBS of pH 7.4 (scan rate 50 mV·s −1 ) at the following: ( A , C ) SPCE (1); HOOC-Phe-SPCE (2); HOOC-Phe-SPCE after EDC/sulfo-NHS activation (3); anti-iFABP-SPCE (4). ( B , D ) blocked anti-iFABP-SPCE (5); iFABP-anti-iFABP-SPCE (6); Biotin-anti-iFABP-iFABP-anti-iFABP-SPCE (7); V 2 O 5 /MWCNT-HRP-Strept-Biotin-anti-iFABP-iFABP-anti-iFABP-SPCE (8). The progressive modification of the electrode surface leads to changes in the electrochemical response, characterized by a decrease in peak currents in CV and an increase in charge transfer resistance (Rct) in EIS, confirming the stepwise assembly of the immunosensor. The equivalent circuits used to adjust the experimental results are shown within the figure, including Rs (solution resistance), Rct (charge transfer resistance), CPE (constant phase element), and Zw (Warburg impedance), allowing accurate fitting of the impedance data.
Techniques Used: Activation Assay, Modification
Figure Legend Snippet: Calibration plot constructed with the developed dual immunosensor for the amperometric determination of iFABP and FC standards in the concentration range studied under optimized experimental conditions. The plots represent the steady-state current responses (i, nA) obtained after addition of H 2 O 2 , showing the simultaneous and independent detection of both biomarkers. Error bars are estimated as triple of the standard deviation of three replicates. Insets show representative chronoamperometric responses for increasing concentrations of FC (top) and iFABP (bottom), illustrating the stepwise increase in signal with analyte concentration.
Techniques Used: Construct, Concentration Assay, Standard Deviation
Figure Legend Snippet: Amperometric responses provided by the developed immunosensor for the following: ( A ) 0 (light pink) and 10 ng mL −1 (dark pink) iFABP or ( B ) 0 (light blue) and 10 ng mL −1 (dark blue) FC in the presence of the following non-target compounds: 10 ng mL −1 FC ( A ) or iFABP ( B ), 5 mg mL −1 hemoglobin (HB), 50 mg mL −1 human serum albumin (HSA), 100 pg mL −1 interferon gamma (INF-γ), 1 mg mL −1 human immunoglobulin G(IgG), 200 pg mL −1 tumoral necrosis factor alpha (TNF-α) and 100 μg mL −1 uric acid (UA). The dashed lines represent the mean signal ±2 standard deviations obtained in the absence of interferents, providing a reference for evaluating potential interference effects. The results demonstrate that the presence of non-target species does not significantly affect the analytical signal, confirming the high selectivity of the immunosensor.
Techniques Used: