Truly Multicolor Emissive Hyperbranched Polysiloxane: Synthesis, Mechanism Study, and Visualization of Controlled Drug Release

Bai, Lihua; Yang, Pengfei; Guo, Liulong; Liu, Susu; Yan, Hongxia

doi:10.1021/acs.biomac.1c01396

Cited by 24 publications

(39 citation statements)

References 39 publications

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“…Yan et al found that the electron cloud of carbonyl and CC bonds in polysiloxane will overlap and form multiple through-space conjugation rings, and blue, green, and red light will be generated under different excitations; hence, the emission mechanism named multiring-induced multicolor emission is proposed . We found that the electronic communication between electron-rich functional groups could be promoted through decreasing the distance and steric hindrance and then generate large spatial electronic delocalizations, and finally, bright blue, green, yellow, and red emissions are observed . These research studies show that the long-wavelength emission of polymers is closely related to the species of functional groups, density of electron-rich atoms, interactions between functional groups, morphologies of aggregates, and so on.…”

Section: Introductionmentioning

confidence: 58%

“…UV–vis absorbance was first studied to confirm the presence of heterogeneous special electronic delocalizations in the aggregates of polymers. In the UV–vis absorbance spectra of HBPSi (Figure a), a peak at 208 is observed, which is caused by the n−σ* electronic transitions of hydroxyl, −Si(O) 3 , and amine groups. , Different with the UV–vis absorbance spectra of HBPSi, new absorbance peaks at about 269, 340, 400, 450, and 500 nm in the UV–vis absorbance spectra of HBPSi-Phe (Figure b), HBPSi-Tyr (Figure c), and HBPSi-Trp (Figure d) are also observed at concentrated solutions, and these new peaks are enhanced with increasing concentrations. The absorbance at 269 nm might come from the π–π* electronic transitions of the conjugated π bonds in the amino acids (Figure S3).…”

Section: Resultsmentioning

confidence: 95%

“…The absorbance at 269 nm might come from the π–π* electronic transitions of the conjugated π bonds in the amino acids (Figure S3). Moreover, the long-wavelength absorptions at 340, 400, 450, and 500 nm come from the large spatial electronic delocalizations. , With increasing the concentration, HBPSi-Phe, HBPSi-Tyr, and HBPSi-Trp gradually aggregate, and then, the conjugated π bonds and electron-rich functional groups are clustered, and the electronic communication is enhanced, forming large spatial electronic delocalizations. Larger spatial electronic delocalizations could generate longer wavelength emissions. − Thus, HBPSi-Phe, HBPSi-Tyr, and HBPSi-Trp might emit long-wavelength emissions.…”

Section: Resultsmentioning

confidence: 99%

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High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

et al. 2022

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Unconventional fluorescent polymers possess the advantages of excellent biocompatibility, environmental friendliness, and facile structural regulation; however, such polymers usually have low fluorescence intensity and quantum yields in the long-wavelength range. In this work, three kinds of high-efficiency long-wavelength emissive hyperbranched polysiloxanes are obtained by introducing aromatic amino acids. These functionalized hyperbranched polysiloxanes have high fluorescence intensity and quantum yields in green, yellow, and red emission regions. Experimental results and density functional theory calculations reveal that the long-wavelength emission comes from the enhanced electronic communication among the conjugated π bonds, electron-rich atoms, and −Si(O)3 and other functional groups. Especially, the conjugated π bonds efficiently enlarge the spatial electronic delocalizations, resulting in the high-efficiency long-wavelength emission. Moreover, the prepared polymers show excellent applications in information encryption and film preparation. This work could serve as a guide to develop high-efficiency long-wavelength unconventional fluorescent polymers.

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Section: Introductionmentioning

confidence: 58%

Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 99%

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High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

et al. 2022

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“…23−26 Yan et al synthesized a multicolor emissive hyperbranched polysiloxane (HBPSi) that they applied to detect metal ions and use as a nanocarrier; it exhibited multicolor fluorescence because of CIE and its cluster size. 27 Interestingly, Yang et al used thiolactone chemistry to synthesize aliphatic polyamides (PAs) that could produce strong fluorescence as a result of polymerization-induced emissions (PIEs); 28 these aliphatic PAs were applied to organelle-specific imaging.…”

Section: Introductionmentioning

confidence: 99%

“…The nonconventional fluorescence observed with nonconjugated moieties can lead to strong fluorescence emissions with excellent photostability because of resistance to photobleaching and nonquenching effects. , Furthermore, nonconjugated HBP nanomaterials featuring multiple hydrogen-bonding interactions can have chemical structures similar to those of biopolymers, with excellent water solubility, chain flexibility, and structural tunability as well as the potential for facile one-pot preparation, environmental friendliness, and use in biological fluorescence imaging. − Nonconventional fluorescent polymers have been applied in various applications, including the detection of metal ions, bioimaging, and nanodrug formulation. − Yan et al synthesized a multicolor emissive hyperbranched polysiloxane (HBPSi) that they applied to detect metal ions and use as a nanocarrier; it exhibited multicolor fluorescence because of CIE and its cluster size . Interestingly, Yang et al used thiolactone chemistry to synthesize aliphatic polyamides (PAs) that could produce strong fluorescence as a result of polymerization-induced emissions (PIEs); these aliphatic PAs were applied to organelle-specific imaging.…”

Section: Introductionmentioning

confidence: 99%

Nonconventional Fluorescent Hyperbranched Polymer Dots as Skin Nanocarriers Constructed from an Olefinic Aliphatic AB₂-Type Monomer

Chang

Chen

Chiang

et al. 2022

ACS Appl. Polym. Mater.

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We constructed an olefinic aliphatic AB2 monomer (π-AB2) for the synthesis of a nonconventional fluorescent hyperbranched polymers (π-HBPs) through self-polymerization. We obtained π-AB2 from N-(3-aminopropyl)diethanolamine and maleic anhydride in three steps with a total yield of 79%. The π-HBPs possessed hyperbranched poly(amido acid) structures with internal alkene moieties, branched amino groups, and carboxyl terminal units. With their nonconjugated hyperbranched structures, the π-HBPs functioned as water-soluble polymer dots. Inter- and intramolecular hydrogen bonding in the π-HBPs resulted in a physically cross-linked structures displaying nonconventional fluorescence. This fluorescence arose from spatial conjugation at the molecular level, leading to clustering-induced emission with the lone pairs of electrons and the π-electrons interacting in a narrow confinement space. The emission of π-HBP 03 occurred at 460 nm upon excitation of 390 nm, with quantum yields of 13.5 and 7.5% at pH 7 and 3, respectively. From an examination of the relationship between chemical structure and photoluminescence, we found that the fluorescence emissions of the HBP without internal alkene moieties and π-HBP 03 (with internal alkene moieties) were 395 and 460 nm, respectively (a red-shift of 65 nm when removing the olefinic units). The self-assembly of π-HBP 03 in aqueous solution produced nanosized (ca. 9.1 nm) particles, as determined through dynamic light scattering. π-HBP 03 is noncytotoxic, with a cell viability of >90% at 1500 μg mL–1. When applied to percutaneous absorption mouse skin, the penetration ability of the π-HBPs increased in various time profiles according to the cluster size and nanostructure of the polymer dots. When we incubated HaCaT cells with π-HBP 03 for 24 h, confocal microscopy revealed that π-HBP 03 became located within the cells. Furthermore, assays revealed that π-HBP 03 displayed effective antioxidant abilities when employed at concentrations of 0.6 and 1.5 mg mL–1.

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Nonconventional aggregation‐induced emission polysiloxanes: Structures, characteristics, and applications

Zhao,

Xu,

et al. 2023

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Nonconventional luminescent materials have been rising stars in organic luminophores due to their intrinsic characteristics, including water‐solubility, biocompatibility, and environmental friendliness and have shown potential applications in diverse fields. As an indispensable branch of nonconventional luminescent materials, polysiloxanes, which consist of electron‐rich auxochromic groups, have exhibited outstanding photophysical properties due to the unique silicon atoms. The flexible Si‐O bonds benefit the aggregation, and the empty 3d orbitals of Si atoms can generate coordination bonds including N → Si and O → Si, altering the electron delocalization of the material and improving the luminescent purity. Herein, we review the recent progress in luminescent polysiloxanes with different topologies and discuss the challenges and perspectives. With an emphasis on the driving force for the aggregation and the mechanism of tuned emissions, the role of Si atoms played in the nonconventional luminophores is highlighted. This review may provide new insights into the design of nonconventional luminescent materials and expand their further applications in sensing, biomedicine, lighting devices, etc.

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Truly Multicolor Emissive Hyperbranched Polysiloxane: Synthesis, Mechanism Study, and Visualization of Controlled Drug Release

Cited by 24 publications

References 39 publications

High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

Nonconventional Fluorescent Hyperbranched Polymer Dots as Skin Nanocarriers Constructed from an Olefinic Aliphatic AB₂-Type Monomer

Nonconventional aggregation‐induced emission polysiloxanes: Structures, characteristics, and applications

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Truly Multicolor Emissive Hyperbranched Polysiloxane: Synthesis, Mechanism Study, and Visualization of Controlled Drug Release

Cited by 24 publications

References 39 publications

High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

High-Efficiency Long-Wavelength Fluorescent Hyperbranched Polysiloxanes: Synthesis, Emission Mechanism, Information Encryption, and Film Preparation

Nonconventional Fluorescent Hyperbranched Polymer Dots as Skin Nanocarriers Constructed from an Olefinic Aliphatic AB2-Type Monomer

Nonconventional aggregation‐induced emission polysiloxanes: Structures, characteristics, and applications

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Nonconventional Fluorescent Hyperbranched Polymer Dots as Skin Nanocarriers Constructed from an Olefinic Aliphatic AB₂-Type Monomer