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Self-assembling Non-conjugated Poly(amide-imide) into Thermoresponsive Nanovesicles with Unexpected Red fluorescence for Bioimaging
摘要: Non-conjugated red fluorescent polymers have been increasingly studied to improve the biocompatibility and penetration depth over conventional fluorescent materials. However, the accessibility of such polymers remains challenging due to the scarcity of non-conjugated fluorophores and lacking relevant mechanism of red-shifted fluorescence. Herein, we discovered that the combination of hydrogen bonding and π-π stacking interactions provides non-conjugated poly(amide-imide) with a large bathochromic shift (> 100 nm) from blue-green fluorescence to red emission. The amphiphilic PEGylated poly(amide-imide) derived from in-situ PEGylation self-assembled into nanovesicles in water, which isolated the aminosuccinimide fluorophore from the solvents and suppressed the hydrogen bonds formation between aminosuccinimide fluorophores and water. Therefore, the fluorescence of PEGylated poly(amide-imide) in water was soundly retained. Furthermore, the strong hydrogen bonding and hydrophobic interactions with water provided PEGylated poly(amide-imide) with a reversible thermoresponsiveness and presented a concentration-dependent behavior. Finally, accompanied with the excellent biostability and photostability, PEGylated poly(amide-imide) exhibited as a good candidate for cell imaging.
关键词: poly(amide-imide),red-shifted fluorescence,self-assembly,bioimaging,nanovesicles
更新于2025-11-14 17:04:02
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Photooxidase-mimicking nanovesicles with superior photocatalytic activity and stability based on amphiphilic amino acid and phthalocyanine co-assembly
摘要: Enzyme mimics have broad applications in catalysis and can assist elucidation of the catalytic mechanism of natural enzymes. However, challenges arise from the design of catalytic sites, the selection of host molecules and their integration into active three-dimensional structures. Herein, we develop a mimic photooxidase by synergetic molecular self-assembly. 9-Fluorenylmethyloxycarbonyl-L-histidine in combination with phthalocyanine shows efficient co-assembly into nanovesicles with flexibly tunable particle size and membrane thickness. The obtained nanovesicles are capable of reactive oxygen-mediated photosensitive oxidation with improved efficiency and stability. This work highlights the co-assembly of simple building blocks into a supramolecular photocatalyst, which might give insight into possible evolutionary paths of photocatalytic membraneous systems and will allow the facile transfer into photosensitive nanoreactors or artificial organelles.
关键词: self-assembly,photooxidase,amino acids,nanovesicles,phthalocyanines
更新于2025-09-23 15:23:52
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Plasmonic Gold Nanovesicles for Biomedical Applications
摘要: Gold nanoparticles (GNPs), with tunable optical properties, bioinertness, and surface multivalent effect, have been widely explored for biomedical applications. As one classical type of GNPs-based assemblies, plasmonic gold nanovesicles (GVs), with a hollow cavity, “solid skeleton” composed of GNPs cores and a “soft body” composed of functional polymers, have attracted considerable attention due to their tunable localized surface plasmon resonance, strong surface-enhanced Raman scattering properties, and high photothermal conversion efficiency. This review summarizes recent advances in biomedical applications for plasmonic GVs. Firstly, the synthesis methods of GVs are mainly including self-assembly and in situ gold growth methods. Secondly, the classification of GVs is described according to the morphology of GNPs cores. Thirdly, different biomedical applications of GVs are elaborated, including in vitro diagnosis, in vivo imaging, and in vivo therapy. Finally, the challenges and perspectives of GVs are discussed.
关键词: cancer therapy,drug delivery,gold nanovesicles,biodetection,cancer imaging
更新于2025-09-23 15:23:52
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Highly cooperative fluorescence switching of self-assembled squaraine dye at tunable threshold temperatures using thermosensitive nanovesicles for optical sensing and imaging
摘要: Thermosensitive fluorescent dyes can convert thermal signals into optical signals as a molecular nanoprobe. These nanoprobes are playing an increasingly important part in optical temperature sensing and imaging at the nano- and microscale. However, the ability of a fluorescent dye itself has sensitivity and accuracy limitations. Here we present a molecular strategy based on self-assembly to overcome such limitations. We found that thermosensitive nanovesicles composed of lipids and a unique fluorescent dye exhibit fluorescence switching characteristics at a threshold temperature. The switch is rapid and reversible and has a high signal to background ratio (>60), and is also highly sensitive to temperature (10–22%/°C) around the threshold value. Furthermore, the threshold temperature at which fluorescence switching is induced, can be tuned according to the phase transition temperature of the lipid bilayer membrane forming the nanovesicles. Spectroscopic analysis indicated that the fluorescence switching is induced by the aggregation-caused quenching and disaggregation-induced emission of the fluorescent dye in a cooperative response to the thermotropic phase transition of the membrane. This mechanism presents a useful approach for chemical and material design to develop fluorescent nanomaterials with superior fluorescence sensitivity to thermal signals for optical temperature sensing and imaging at the nano- and microscales.
关键词: fluorescence switching,optical sensing,nanovesicles,thermosensitive fluorescent dyes,imaging
更新于2025-09-11 14:15:04
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Photooxidase-mimicking nanovesicles with superior photocatalytic activity and stability based on amphiphilic amino acid and phthalocyanine co-assembly
摘要: Enzyme mimics have broad applications in catalysis and can assist elucidation of the catalytic mechanism of natural enzymes. However, challenges arise from the design of catalytic sites, the selection of host molecules and their integration into active three-dimensional structures. Herein, we develop a mimic photooxidase by synergetic molecular self-assembly. 9-Fluorenylmethyloxycarbonyl-L-histidine in combination with phthalocyanine shows efficient co-assembly into nanovesicles with flexibly tunable particle size and membrane thickness. The obtained nanovesicles are capable of reactive oxygen-mediated photosensitive oxidation with improved efficiency and stability. This work highlights the co-assembly of simple building blocks into a supramolecular photocatalyst, which might give insight into possible evolutionary paths of photocatalytic membraneous systems and will allow the facile transfer into photosensitive nanoreactors or artificial organelles.
关键词: nanovesicles,photooxidase,phthalocyanines,self-assembly,amino acids
更新于2025-09-04 15:30:14