A Rainbow Structural‐Color Chip for Multisaccharide Recognition

Qin, Meng; Huang, Yu; Li, Yanan; Su, Meng; Chen, Bingda; Sun, Heng Hu; Yong, Peiyi; Ye, Changqing; Li, Fengyu; Song, Yanlin

doi:10.1002/ange.201602582

Cited by 37 publications

(16 citation statements)

References 44 publications

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“…The advantage of the extended‐gate structure was to avoid the influence of semiconductor films in the aqueous media. Other types of biosensors for detecting trimethylamine, urea, and multisaccharide have also been fabricated and studied.…”

Section: Flexible Biosensorsmentioning

confidence: 99%

An Overview of the Development of Flexible Sensors

et al. 2017

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Flexible sensors that efficiently detect various stimuli relevant to specific environmental or biological species have been extensively studied due to their great potential for the Internet of Things and wearable electronics applications. The application of flexible and stretchable electronics to device-engineering technologies has enabled the fabrication of slender, lightweight, stretchable, and foldable sensors. Here, recent studies on flexible sensors for biological analytes, ions, light, and pH are outlined. In addition, contemporary studies on device structure, materials, and fabrication methods for flexible sensors are discussed, and a market overview is provided. The conclusion presents challenges and perspectives in this field.

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Section: Flexible Biosensorsmentioning

confidence: 99%

An Overview of the Development of Flexible Sensors

et al. 2017

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“…In addition to the special recognition of one type of analyte, the multiplex detection of analytes on the same structure is extremely important. The Song group recently demonstrated how a photonic crystal film exhibited structural colors in consecutive spectra, which was attributed to the long‐range ordered arrangement of latex particles. The angle‐dependent structural colors allowed the photonic crystal matrix to be used as a rainbow‐colored chip to enhance different fluorescence signals corresponding to the recognition of different analytes.…”

Section: Manipulating Luminescence Of Light Emitters By 3d Photonic Cmentioning

confidence: 99%

Manipulating Luminescence of Light Emitters by Photonic Crystals

et al. 2018

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dispersion by semiconductor devices based on the electron energy bandgap-the forbidden energies separating allowed energy bands. An example of photonic crystals with simple periodic arrays formed from dielectric spheres is shown in Figure 1. According to Bragg's equation, [3] the wavelength of the photons scattered from the crystal lattice can be calculated by the following formula (Equation (1)where d is the diameter of the sphere, m is the Bragg reflection order, and θ is the angle between the normal and incident light. The value of n a is defined as the weighted sum of sphere portion refractive indices and the gap portion (Equation (2)) [3] ∑ φ = n n i i a 2 2(2)where n is the refractive index of different components inside photonic crystals and φ i is the volume fraction of each i portion. For the close-packed structure, φ i of the sphere portion is 0.74. Photon propagation can be precisely controlled by designing a photonic crystal with a specific photonic bandgap. Hence, a future trend in the design of photonic crystals may lie in the modification and realization of spontaneous emission by light emitters integrated with these crystals. [4][5][6] Spontaneous emission refers to an optical process in which a quantum mechanical system in an excited state returns to a lower-energy or ground state and releases energy in the form of a photon. The quantum system could be an atom, molecule or nanocrystal. The photoluminescence (PL) produced by spontaneous emission plays a crucial role in conventional modern technologies used in daily lives, such as television screens (cathode ray tubes), plasma display panels, and fluorescence tubes.While spontaneous emission has enabled the progress of several technologies, uncontrolled spontaneous emission can limit the performance of photonic devices in many applications. One such limitation in device performance in light-emitting diodes (LEDs) occurs when an excessive number of photons generated from spontaneous emission are confined or trapped within the device. This shortcoming is also observed in laser operation when photon emission fails to couple with lasing processes, resulting in energy loss and noise in the signal output. Consequently, precise control over the propagation of spontaneous emission is critical. Due to their ability to manipulate light The modulation of luminescence is essential because unwanted spontaneousemission modes have a negative effect on the performance of luminescencebased photonic devices. Photonic crystals are promising materials for the control of light emission because of the variation in the local density of optical modes within them. They have been widely investigated for the manipulation of the emission intensity and lifetime of light emitters. Several groups have achieved greatly enhanced emission by depositing emitters on the surface of photonic crystals. Herein, the different modulating effects of photonic crystal dimensions, light-emitter positions, photonic crystal structure type, and the refractive index of photonic crystal building bl...

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“…colloidal crystal | self-healing | inverse opal | structural color | hydrogel S tructural colors, arising from intrinsic periodic nanostructures and resulting in the interaction of light with these photonic nanostructures, have attracted much interest because of the fascination associated with the display of various brilliant examples (1)(2)(3)(4)(5)(6). The creatures displaying brilliant structural colors are prevalent in nature, and their life, including communication, shielding, and other biological functions, is closely linked with these structural colors (7).…”

mentioning

confidence: 99%

Bio-inspired self-healing structural color hydrogel

Chen

Zhao

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

259

177

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Biologically inspired self-healing structural color hydrogels were developed by adding a glucose oxidase (GOX)- and catalase (CAT)-filled glutaraldehyde cross-linked BSA hydrogel into methacrylated gelatin (GelMA) inverse opal scaffolds. The composite hydrogel materials with the polymerized GelMA scaffold could maintain the stability of an inverse opal structure and its resultant structural colors, whereas the protein hydrogel filler could impart self-healing capability through the reversible covalent attachment of glutaraldehyde to lysine residues of BSA and enzyme additives. A series of unprecedented structural color materials could be created by assembling and healing the elements of the composite hydrogel. In addition, as both the GelMA and the protein hydrogels were derived from organisms, the composite materials presented high biocompatibility and plasticity. These features of self-healing structural color hydrogels make them excellent functional materials for different applications.

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A Rainbow Structural‐Color Chip for Multisaccharide Recognition

Cited by 37 publications

References 44 publications

An Overview of the Development of Flexible Sensors

An Overview of the Development of Flexible Sensors

Manipulating Luminescence of Light Emitters by Photonic Crystals

Bio-inspired self-healing structural color hydrogel

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