Handbook of Aggregation-Induced Emission, Volume 2. Группа авторов

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Handbook of Aggregation-Induced Emission, Volume 2 - Группа авторов


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side of the figure); two types of strategies can be envisioned: (d) confocal fluorescence images of FFSNPs for HeLa cells: overlay of fluorescence image and bright‐field image [20].

      Source: Reproduced from Ref. [20] with permission from the Royal Society of Chemistry.

      Tian et al. successfully designed and synthesized a novel fluorescent molecule 3‐4 based on a diselenide bond and DSA AIEgens. The compound 3‐4 can self‐assemble into uniform nanoparticles via the generally used nanoprecipitation method, and the nanoparticles emit a bright orange fluorescence. The redox‐responsive fluorescent nanoparticles based on the diselenide bond and DSA AIEgens have potential applications in cell imaging and reduction‐sensitive drug delivery for selective cancer therapy [74].

      Stable AIEgen‐based nanoparticles of different shapes were prepared by assembling the copolymer and DSA and applied in noninvasive long‐term imaging. The nanoparticles have excellent physical and photostability under physiological conditions. The in vitro experimental results verified that these AIE‐active organic nanoparticles are biocompatible and internalized through various pathways of cellular uptake. The long‐term imaging ability was verified by the in vitro and in vivo experiments. It was confirmed that the rod‐like nanoparticles were significantly more internalized than the spherical particles, and they exhibited a better imaging effect [76].

      Tian et al. prepared fluorescent nanoparticles by constructing a coassembly of human papillomavirus (HPV) capsid protein L1 and a complex consisting of DNA and an AIE molecule 3‐5. The virus‐like particles (VLPs) of HPV encapsulate the complex via electrostatic interaction. The coassembled nanoparticles, 3‐5‐DNA@VLPs, demonstrated a homogeneous size of ∼53 nm and enhanced fluorescence. Notably, the strong cell‐entry ability of VLPs endowed the AIE–DNA complex to enter the cell easily, which led to efficient brighter imaging in HeLa and normal 293T cell lines. Therefore, this work supplied a powerful approach to deliver the AIEgen into cells, which not only provided a simple, fast, biocompatible, and highly efficient fluorescence tool for in vivo cell imaging but also largely extended the bioapplications of AIEgens [77].

      AIEgen‐based poly(l‐lactic‐co‐glycolic acid) (PLGA) magnetic nanoparticles to localize cytokine vascular endothelial growth factor (VEGF) were developed. The nanoparticles, as a novel theranostic system, could be utilized for simultaneous photothermal therapy and magnetic resonance imaging, which was applicable to early diagnostics and treatment of cancer cells. The system was constructed by loading the oleic acid‐Fe3O4 and an AIEgen, triphenylamine‐divinylanthracene‐dicyano, inside the PLGA shell, which was then modified with anti‐VEGF‐A antibodies. By adjusting the proportion of AIEgens and Fe3O4, this system showed a strong red emission desirable for early cancer cell diagnosis, as well as magnetic properties suitable for application in magnetic resonance imaging [78].

      Besides the AIE small molecules, there are also some AIE macromolecules applied in the fluorescent bioimaging. A series of random copolymers (polymer 3‐6 in Figure 2.8) based on poly[N‐(2‐hydroxypropyl)methacrylamide] (PHPMA) and hydrophobic AIE fluorophores DSA were prepared. It indicated that enhancing the molar fractions of the hydrophobic AIE fluorophores can lead to increasing the quantum efficiencies of the copolymers. These polymers were almost nonemissive in the solvent of dimethyl sulfoxide (DMSO) but emitted strong fluorescence in the mixed solvent of DMSO/water. It was confirmed that these polymers formed small micelles with an average diameter of about 10 nm in the aqueous solutions. Although the DSA fluorophore is water‐insoluble, when it chemically conjugates with the biocompatible polymer PHPMA, the prepared final copolymers, which are noncytotoxic to living cells, can be applied in biological condition for bioimaging [23]. In addition, by using PHPMA and DSA fluorophores, they prepared a new series of random copolymers (polymer 3‐7 in Figure 2.8). Similarly, the fluorescence quantum yields of the AIE copolymers in aqueous solutions increase with increasing the molar fractions of the hydrophobic AIE fluorophores and/or the trifluoromethyl moieties. It was the first report that the AIE fluorophores were integrated with fluorine‐containing polymers to manipulate the quantum yields of the AIE fluorophores [79].

Schematic illustration of confocal laser scanning microscopy images of HeLa cells after incubation with 3-9@PS-PVP (Start3-9End in poly(styrene)-poly(4-vinylpyridine nanoparticles) (with a fluorogen loading of 10%) for 16 hours at 37 °C.

      Source: Reproduced from Ref. [81] with permission from the Royal Society of Chemistry.

      Wei et al. utilized phospholipid monomer firstly to fabricate cross‐linked fluorescent polymeric nanoparticles by using the AIE dye 3‐10 based on DSA fluorophore [86]. The prepared


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