Design and Synthesis of Fluorescent Nanocelluloses for Sensing and Bioimaging Applications

Recent materials research based on fluorescent nanocelluloses (NCs) used in the field of sensing and bioimaging is reviewed. Many designed morphologies have been reported, such as nanoparticles, fibers, nanopapers, hydrogels and aerogels, that have been produced by physical or chemical methods. In t...

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Veröffentlicht in:	ChemPlusChem (Weinheim, Germany) Germany), 2020-03, Vol.85 (3), p.487-502
Hauptverfasser:	Zhang, Zhao, Liu, Gang, Li, Xinping, Zhang, Sufeng, Lü, Xingqiang, Wang, Yaoyu
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerogels Animals Anions Bacteria - chemistry Biocompatibility Biocompatible Materials - chemical synthesis Biodegradability Biodegradation bioimaging Biosensing Techniques Cations Cell Membrane Permeability Cell membranes Cellulose - chemistry Chemistry clinical diagnostics Detection Fluorescence Fluorescent Dyes - chemistry Humans Hydrogels Hydrogen-Ion Concentration Ions - chemistry Medical imaging Metals - chemistry Morphology nanocellulose Nanoparticles Nanostructures - chemistry Optical Imaging Optical properties Polarized light sensing Spectrometry, Fluorescence Surface Properties Temperature Toxicity
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creator	Zhang, Zhao Liu, Gang Li, Xinping Zhang, Sufeng Lü, Xingqiang Wang, Yaoyu
description	Recent materials research based on fluorescent nanocelluloses (NCs) used in the field of sensing and bioimaging is reviewed. Many designed morphologies have been reported, such as nanoparticles, fibers, nanopapers, hydrogels and aerogels, that have been produced by physical or chemical methods. In the field of sensing and bioimaging, these studies have involved, but not been limited to, special optical properties including fluorescence, long‐lived luminescence, polarized light, and/or aggregation‐induced emission. The fluorescence sensing platforms can be categorized according to stimuli such as pH and temperature, as well as the presence of toxic compounds, and anions and metal cations. In addition, NCs exhibit unique low toxicity, good biocompatibility, biodegradability and cell membrane penetration, and can be modified into fluorescent nanoprobes for in vivo imaging and tracing. As an excellent platform for fluorescent sensing and bioimaging, NCs are bound to be increasingly studied and widely applied in the field of production and life sciences. A strong thread: The design of fluorescent nanocelluloses (NCs) for sensing and bioimaging applications are reviewed. NCs can be incorporated into nanopaper, hydrogels, aerogels, fibers, and nanoparticle systems through physical or chemical methods. The resulting optical properties include fluorescence, long‐lived luminescence, chiral nematic liquid crystals, and aggregation‐induced emission.
doi_str_mv	10.1002/cplu.201900746
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A strong thread: The design of fluorescent nanocelluloses (NCs) for sensing and bioimaging applications are reviewed. NCs can be incorporated into nanopaper, hydrogels, aerogels, fibers, and nanoparticle systems through physical or chemical methods. 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A strong thread: The design of fluorescent nanocelluloses (NCs) for sensing and bioimaging applications are reviewed. NCs can be incorporated into nanopaper, hydrogels, aerogels, fibers, and nanoparticle systems through physical or chemical methods. 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Many designed morphologies have been reported, such as nanoparticles, fibers, nanopapers, hydrogels and aerogels, that have been produced by physical or chemical methods. In the field of sensing and bioimaging, these studies have involved, but not been limited to, special optical properties including fluorescence, long‐lived luminescence, polarized light, and/or aggregation‐induced emission. The fluorescence sensing platforms can be categorized according to stimuli such as pH and temperature, as well as the presence of toxic compounds, and anions and metal cations. In addition, NCs exhibit unique low toxicity, good biocompatibility, biodegradability and cell membrane penetration, and can be modified into fluorescent nanoprobes for in vivo imaging and tracing. As an excellent platform for fluorescent sensing and bioimaging, NCs are bound to be increasingly studied and widely applied in the field of production and life sciences. 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subjects	Aerogels Animals Anions Bacteria - chemistry Biocompatibility Biocompatible Materials - chemical synthesis Biodegradability Biodegradation bioimaging Biosensing Techniques Cations Cell Membrane Permeability Cell membranes Cellulose - chemistry Chemistry clinical diagnostics Detection Fluorescence Fluorescent Dyes - chemistry Humans Hydrogels Hydrogen-Ion Concentration Ions - chemistry Medical imaging Metals - chemistry Morphology nanocellulose Nanoparticles Nanostructures - chemistry Optical Imaging Optical properties Polarized light sensing Spectrometry, Fluorescence Surface Properties Temperature Toxicity
title	Design and Synthesis of Fluorescent Nanocelluloses for Sensing and Bioimaging Applications
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