Gold coated porous silicon nanocomposite as a substrate for photoluminescence-based immunosensor suitable for the determination of Aflatoxin B1.

6533b822fe1ef96bd127d913

RESEARCH PRODUCT

Gold coated porous silicon nanocomposite as a substrate for photoluminescence-based immunosensor suitable for the determination of Aflatoxin B1.

Maryna Koval Valentyn Smyntyna Valerii Myndrul Roman Viter Viesturs Silamiķelis Arunas Ramanavicius Igor Iatsunskyi Maryna Savchuk N.f. Starodub

subject

Silicon Photoluminescence Aflatoxin B1 Silicon Analytical chemistry chemistry.chemical_element Nanoparticle Food Contamination 02 engineering and technology Substrate (electronics)Biosensing Techniques 010402 general chemistry Electrochemistry Porous silicon 01 natural sciences Analytical Chemistry Nanocomposites Limit of Detection Immunoassay Nanocomposite Chemistry 021001 nanoscience & nanotechnology 0104 chemical sciences Luminescent Measurements Thermodynamics High Energy Physics::Experiment Gold 0210 nano-technology Layer (electronics)Antibodies Immobilized Porosity

description

Abstract A rapid and low cost photoluminescence (PL) immunosensor for the determination of low concentrations of Aflatoxin B1 (AFB1) has been developed. This immunosensor was based on porous silicon (PSi) covered by thin gold layer (Au) and modified by antibodies against AFB1 (anti-AFB1). PSi layer was formed on silicon substrate, then the surface of PSi was covered by 30 nm layer of gold (PSi/Au) using electrochemical and chemical deposition methods and in such ways PSi/Au (El.) and PSi/Au (Chem.) structures were formed, respectively. In order to find PSi/Au the most efficiently suitable for PL-based sensor design, structure several different PSi/Au (El.) and PSi/Au (Chem.) structures were designed while using different conditions for electrochemical or chemical deposition of gold layer. It was shown that during the formation of PSi/Au structure crystalline Au nanoparticles uniformly coated the surface of the PSi pores. PL spectroscopy of PSi/Au nanocomposites was performed at room temperature and it showed a wide emission band centered at 700 nm. Protein A was covalently immobilized on the surface of PSi/Au (El.) and PSi/Au (Chem.) forming PSi/Au (El.) /Protein-A and PSi/Au (Chem.) /Protein-A structures, respectively. In the next step PSi/Au (El.) /Protein-A and PSi/Au (Chem.) /Protein-A structures were modified by anti-AFB1 and in such way a structures (PSi/Au (El.) /Protein-A/anti-AFB1 and PSi/Au (Chem.) /Protein-A/anti-AFB1) sensitive towards AFB1 were designed. The PSi/Au (El.) /Protein-A/anti-AFB1- and PSi/Au (Chem.) /Protein-A/anti-AFB1-based immunosensors were tested in a wide range of AFB1 concentrations from 0.001 upon 100 ng/ml. Interaction of AFB1 with PSi/Au (El.) /Protein-A/anti-AFB1- and PSi/Au (Chem.) /Protein-A/anti-AFB1-based structures resulted PL quenching. The highest sensitivity towards AFB1 was determined for PSi/Au (El.) /Protein-A/anti-AFB1-based immunosensor and it was in the range of 0.01–10 ng/ml. The applicability of PSi/Au-based structures as new substrates suitable for PL-based immunosensors is discussed.

year	journal	country	edition	language
2017-12-01	Talanta

10.1016/j.talanta.2017.07.054 https://pubmed.ncbi.nlm.nih.gov/28841993