Interferometric multilayered nanomaterials for imaging unlabeled biorecognition events

•Multilayered nanomaterials for label-free biosensing by common-path interferometry.•Superposed films of gold, Ag-In-Sb-Te alloy and zinc sulphide on polycarbonate.•Simple, compact, and low-cost microarray scanner based on standard DVD laser units.•Sensitive detection of unlabeled sulfasalazine in a...

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Published in:Sensors and actuators. B, Chemical Chemical, 2021-03, Vol.331, p.129289, Article 129289
Main Authors: Sancho-Fornes, Gabriel, Avella-Oliver, Miquel, Carrascosa, Javier, Puchades, Rosa, Maquieira, Ángel
Format: Article
Language:English
Subjects:
Antimony
Biosensor
Imaging
Immunoassay
Interferometry
Ion beams
Label-free
Low molecular weights
Nanomaterial
Nanomaterials
Optical disks
Silver
Substrates
Sulfasalazine
Tellurium
Zinc sulfide
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Summary:•Multilayered nanomaterials for label-free biosensing by common-path interferometry.•Superposed films of gold, Ag-In-Sb-Te alloy and zinc sulphide on polycarbonate.•Simple, compact, and low-cost microarray scanner based on standard DVD laser units.•Sensitive detection of unlabeled sulfasalazine in a competitive immunoassay.•Fast one-shot color-based RGB imaging system for point-of-care biosensing. There is an intense scientific activity on nanomaterials for biosensing, supported by their great potential to conceive powerful applications in chemistry, biology, and medicine. In addition to meet the required analytical parameters, the social impact of these advances is also highly influenced by cost, simplicity, and portability aspects, which are critical in label-free systems. This paper addresses the design, development, and experimental assessment of multilayered nanomaterials to transduce unlabeled biorecognition assays as both constructive and destructive interferences, by means of simple and effective imaging setups. The materials rely on superposed nanometric films of metals (gold and Ag-In-Sb-Te alloy) and a dielectric (zinc sulphide) deposited on a polymeric substrate. They are tailored to display maximal (constructive and destructive) interferences for immunoassays performed on their surface, and then fabricated by sputtering and characterized by focused ion beam scanning electron microscopy. Herein we also address the development of a simple optical setup that exploits standard DVD laser units to scan by imaging the reflected interferometric response of microarrayed immunoassays. The bioanalytical performance of the approach is experimentally assessed using a representative model immunoassay (BSA/anti-BSA) and a competitive immunoassay to quantify a low molecular weight drug (sulfasalazine), reaching detection limits of 460 and 11 ng mL−1 of unlabeled targets, respectively. This study also explores two alternative one-shot interferometric imaging approaches that provide insights into simpler and faster strategies for label-free biosensing.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2020.129289