Bioinspired Photonic Barcodes with Graphene Oxide Encapsulation for Multiplexed MicroRNA Quantification

Bian, Feika; Wu, Jindao; Wang, Huan; Sun, Lingyu; Shao, Changmin; Wang, Yu; Li, Zhiyang; Wang, Xuehao; Zhao, Yuanjin

doi:10.1002/smll.201803551

Cited by 47 publications

(38 citation statements)

References 48 publications

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“…The characteristic reflection peak position of colloidal crystal barcodes which consist of different size silica nanoparticles could be calculated according to Bragg's equation: λ = 1.633dn average , 29,37 where λ represents the wavelength peak of colloidal crystal barcodes, the diameter of adjacent SiO 2 nanoparticles is represented by d, and n average is on behalf of the average refractive index of the colloidal crystal ( Figure 2d). 31,37 The constitutes of colloidal crystal keep unchanged, n average is unchanged, and λ is only related to d. Hence, these characteristics demonstrate that a series of various reflection wavelength could be obtained by adjusting diameter of silica nanoparticles. Besides, the microstructure of the colloidal crystal barcodes was recorded by scanning electron microscopy (SEM), and the barcodes have a uniform diameter size of silica nanoparticles is 200 ± 10 nm and formed an ordered hexagonal alignment (Figure 2e,f).…”

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confidence: 88%

Label-Free Quantifications of Multiplexed Mycotoxins by G-Quadruplex Based on Photonic Barcodes

et al. 2020

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Multiplexed quantification of mycotoxins is of great significance in food safety. Here, novel photonic crystal (PhC) barcodes with G-quadruplex aptamer encapsulated for label-free multiplex mycotoxins quantification are developed. The probes are immobilized on PhC barcodes to form a molecular beacon (MB), which contains the sequences of mycotoxin aptamers and a Gquadruplex. In the presence of the target, the hairpin structure of MB would open and the region of the G-quadruplex is exposed, which subsequently combines with Thioflavin T (ThT) to produce fluorescence. The relative fluorescence intensity increased as the mycotoxins concentration increased in a linear range from 1.0 pg/ mL to 100 ng/mL. Moreover, the multiplexed mycotoxins quantification could be achieved by tuning the structural color of the PhC barcodes. We demonstrate that this method with high accuracy and specificity for multiplexed detection of mycotoxins, with the sensitivity of the detection as low as 0.70 pg/mL. Our results show that G-quadruplex-encapsulated PhC barcodes offer a novel simple and label-free pathway toward the multiplex screen assay of mycotoxins for food safety.

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confidence: 88%

Label-Free Quantifications of Multiplexed Mycotoxins by G-Quadruplex Based on Photonic Barcodes

et al. 2020

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“…demonstrated the integration of mussels (i.e., DA) into functional materials for achieving adhesive features. [22][23][24][25] Thus, when the structural-color materials are combined with DA, they are imparted with good adhesion. Furthermore, feathers of many kinds of birds often display vivid and bright structural colors.…”

Section: Progress and Potentialmentioning

confidence: 99%

Bio-Inspired Self-Adhesive Bright Non-iridescent Graphene Pigments

Liu

Shao

Wang

et al. 2019

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Inspired by feathers' brightness and mussels' adhesivity, we develop polydopamine (PDA)-adhered multi-shell graphene oxide (GO)-encapsulated silica nanoparticles. Their derived non-iridescent pigments through spraying demonstrate amorphous structure and brighter structural color that is not easily damaged, due to the existence of GO (serving as dark element to improve color saturation) and PDA (providing color stability by self-adhesivity). The inverse opal hydrogel generated from the pigment template also shows vivid structural color, as well as photothermal responsiveness and self-healing capacity.

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“…Bian et al prepared colloidal crystal barcodes by microfluidics and modified them for quantification of miRNA ( Figure a) . The calcined colloidal crystal barcodes were incubated in Tris buffer (pH = 8.5) containing dopamine to form a polydopamine functional layer by self‐polymerization on the surface of the colloidal crystal barcodes.…”

Section: Applicationsmentioning

confidence: 99%

Colloidal Crystals from Microfluidics

Bian

Sun

Cai

et al. 2019

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Colloidal crystals are of great interest to researchers because of their excellent optical properties and broad applications in barcodes, sensors, displays, drug delivery, and other fields. Therefore, the preparation of high quality colloidal crystals in large quantities with high speed is worth investigating. After decades of development, microfluidics have been developed that provide new choices for many fields, especially for the generation of functional materials in microscale. Through the design of microfluidic chips, colloidal crystals can be prepared controllably with the advantages of fast speed and low cost. In this Review, research progress on colloidal crystals from microfluidics is discussed. After summarizing the classifications, the generation of colloidal crystals from microfluidics is discussed, including basic colloidal particles preparation, and their assembly inside or outside of microfluidic devices. Then, applications of the achieved colloidal crystals from microfluidics are illustrated. Finally, the future development and prospects of microfluidic‐based colloidal crystals are summarized.

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Bioinspired Photonic Barcodes with Graphene Oxide Encapsulation for Multiplexed MicroRNA Quantification

Cited by 47 publications

References 48 publications

Label-Free Quantifications of Multiplexed Mycotoxins by G-Quadruplex Based on Photonic Barcodes

Label-Free Quantifications of Multiplexed Mycotoxins by G-Quadruplex Based on Photonic Barcodes

Bio-Inspired Self-Adhesive Bright Non-iridescent Graphene Pigments

Colloidal Crystals from Microfluidics

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