Aggregation Behavior and Antioxidant Properties of Amphiphilic Fullerene C<sub>60</sub> Derivatives Cofunctionalized with Cationic and Nonionic Hydrophilic Groups

Chen, Mengjun; Zhou, Shengju; Guo, Luxuan; Wang, Lin; Yao, Fuxin; Hu, Yuanyuan; Li, Hongguang; Hao, Jingcheng

doi:10.1021/acs.langmuir.8b03681

Cited by 22 publications

(37 citation statements)

References 71 publications

(126 reference statements)

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“…It then slows down at relatively large concentrations of the microcapsule, which reaches ∼86% at 100 μg mL –1 and ∼93% at 1000 μg mL –1 (Figure a, b, Figure S9). The capability of the microcapsules to scavenge OH· – is comparable to that exhibited by the cationic C 60 derivative bearing a Percec monodendron terminated with three oligo(poly(ethylene oxide)) ( o -PEO) chains at the 3,4,5-position, which shows polymorphic aggregation behavior in water with the formation of vesicles, nanorods, and nanotubes . It is slightly weaker than that exhibited by the C 60 derivative with three o -PEO chains at the 2,3,4-position in the Percec monodendron, which forms nanowires in water .…”

Section: Resultsmentioning

confidence: 83%

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Chen

Yin

Zhang

et al. 2019

ACS Appl. Bio Mater.

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Fullerene C60 (refers to C60 hereafter) has a unique three-dimensional architecture and intriguing physicochemical properties. It has great potential applications in materials chemistry and life science. However, a big obstacle for the widespread application of C60 lies in the limited strategies to make supramolecular structures with diverse morphologies and functions. Herein, we report a strategy to prepare C60-based, magnetic microcapsules which can be used as external antioxidants to effectively attenuate oxidative stress. The microcapsules are composed of fullerenol, a highly water-soluble C60 multiadduct, and iron ions (Fe3+) released from a rusty nail. They can be easily obtained through coordination between the hydrophilic functional groups in fullerenol and Fe3+ with polystyrene microspheres as templates. The fullerenol/Fe3+ microcapsules have good colloidal stability both in water and serum. Their biocompatibility has been confirmed by in vitro tests on HEK293 and Hela cells. Electron spin resonance measurements indicate that the fullerenol/Fe3+ microcapsules can effectively scavenge hydroxyl radicals (OH·–) produced by H2O2, which greatly improves the living environment of the cells. The fullerenol/Fe3+ microcapsules exhibit ferromagnetic properties and can respond to the external magnetic field, enabling magnetic manipulation, and/or separation in practical applications.

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Section: Resultsmentioning

confidence: 83%

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Chen

Yin

Zhang

et al. 2019

ACS Appl. Bio Mater.

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“…The MonoaminoC 60 forms larger aggregates around 354 nm with observed zeta potential at +31 mV; in contrast HexakisaminoC 60 seems to predominantly aggregate around 99 nm, indicating a surface of charge of +29 mV. Both aminofullerenes present a relatively good degree of stability, and the smaller aggregates and possibly a different morphology of Hexakisadduct aggregates may be partially explained by a different critical packing parameter p …”

Section: Resultsmentioning

confidence: 96%

“…41 The MonoaminoC 60 forms larger aggregates around 354 nm with observed zeta potential at +31 mV; in contrast Hexakisami-noC 60 seems to predominantly aggregate around 99 nm, indicating a surface of charge of +29 mV. Both aminofullerenes present a relatively good degree of stability, and the smaller aggregates and possibly a different morphology of Hexakisadduct aggregates may be partially explained by a different critical packing parameter p. 42 The infrared spectra of engineered water-soluble fullerenes (MonoaminoC 60 and HexakisaminoC 60 ) have been analyzed considering two spectral regions: (1) 2250−3800 cm −1 and (2) 400−1900 cm −1 (Figure 2C). The bands arrangement found in relation to the HexakisaminoC 60 and MonoaminoC 60 are quite similar, wherein small differences as for the number of bands, their intensity, or positions result from the number of functional groups anchored to the fullerene scaffold.…”

Section: ■ Results and Discussionmentioning

confidence: 98%

Developing [60]Fullerene Nanomaterials for Better Photodynamic Treatment of Non-Melanoma Skin Cancers

Serda

Szewczyk

Krzysztyńska-Kuleta

et al. 2020

ACS Biomater. Sci. Eng.

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Skin cancer is the most common cancer in the U.S.A. and Europe. Its subtype, squamous skin carcinoma (SCC), if allowed to grow, has the potential to metastasize and can become deadly. Currently, carbon nanomaterials are being developed to treat cancer due to their attractive physicochemical and biological properties such as an enhanced permeability effect and their ability to produce reactive oxygen species. Here, we describe the synthesis of two water-soluble aminofullerenes (MonoaminoC60 and HexakisaminoC60), which were evaluated as novel [60]fullerene based photosentizers exhibiting anticancer properties. Moreover, the previously described neutral glycofullerene GF1 and its peracetylated lipophilic precursor MMS48 were compared with the aminofullerenes for their ability to generate reactive oxygen species and oxidize lipids. Remarkably, the generation of singlet oxygen and a superoxide radical by HexakisaminoC60 was found to be markedly elevated in the presence of bovine serum albumin and NADH, respectively. Mechanistic studies of lipid peroxidation using cholesterol as a unique reporter molecule revealed that although all four fullerene nanomaterials primarily generated singlet oxygen, superoxide anion was also formed, which suggest a mixed mechanism of action (in which Type I and Type II photochemistry is involved). The [60]fullerene derivative HexakisaminoC60 was also studied for its phototoxicity in squamous skin cancer cell line (A431) using the MTT test and propidium iodide staining.

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“…Some previous reports might be beneficial for understanding our results. The affinity of hydrophobic fullerene toward protein is higher than that of fullerenol, a water-soluble derivative of fullerene, because the hydrophobic fullerene moiety is able to control the aggregation status of the fullerenyl derivative, and thus, to influence antioxidative property …”

Section: Resultsmentioning

confidence: 99%

“…The affinity of hydrophobic fullerene toward protein is higher than that of fullerenol, a water-soluble derivative of fullerene, 30 because the hydrophobic fullerene moiety is able to control the aggregation status of the fullerenyl derivative, and thus, to influence antioxidative property. 31 To gain further insight into the function of the fullerene moiety on the antioxidative effect, we select 7 and 8 as well as 13 and 14 as the model compounds to test their binding constants (K) with the DNA strand. As shown in eq 8, if a guest compound can intercalate with DNA stand to form a DNA complex, the constant (K) of the guest molecule binding with the DNA strand is expressed by eq 9.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Attaching a Dipeptide to Fullerene as an Antioxidant Hybrid against DNA Oxidation

Zhao

Liu

2021

Chem. Res. Toxicol.

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Emerging evidence has revealed that oxidative damages of DNA correlate with the pathogenesis of some diseases, and numerous investigations have also suggested that supplementation of antioxidants is beneficial for keeping health by rectifying in vivo redox status. Here, we construct antioxidative dipeptides with the Ugi four-component reaction (comprising p-aminobenzyl alcohol, benzaldehyde, or vanillin, a series of antioxidative carboxylic acids and isocyanides as reagents) and then attempt to attach the dipeptides to [60]fullerene by the Bingel reaction. However, this endeavor does not lead to the amelioration of the radical-scavenging property because abilities of fullerenyl dipeptides to trap 2,2′-diphenyl-1-picrylhydrazyl and galvinoxyl radicals are still dependent upon the phenolic hydroxyl group in the dipeptide scaffold rather than upon the fullerenyl group. Alternatively, when the obtained fullerenyl dipeptides are evaluated in a peroxyl radical-induced oxidation of DNA, it is found that introducing a fullerene moiety into dipeptide enables antioxidative effect to be enhanced 20−30% because the fullerene moiety facilitates the corresponding dipeptide to intercalate with DNA strands, and thus, to increase the antioxidative efficacy. Our results suggest that connecting an antioxidative skeleton with the hydrophobic fullerene moiety might lead to a series of novel antioxidant hybrids applied for the inhibition of DNA oxidation.

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Aggregation Behavior and Antioxidant Properties of Amphiphilic Fullerene C₆₀ Derivatives Cofunctionalized with Cationic and Nonionic Hydrophilic Groups

Cited by 22 publications

References 71 publications

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Developing [60]Fullerene Nanomaterials for Better Photodynamic Treatment of Non-Melanoma Skin Cancers

Attaching a Dipeptide to Fullerene as an Antioxidant Hybrid against DNA Oxidation

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Aggregation Behavior and Antioxidant Properties of Amphiphilic Fullerene C60 Derivatives Cofunctionalized with Cationic and Nonionic Hydrophilic Groups

Cited by 22 publications

References 71 publications

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Magnetic and Biocompatible Fullerenol/Fe(III) Microcapsules with Antioxidant Activities

Developing [60]Fullerene Nanomaterials for Better Photodynamic Treatment of Non-Melanoma Skin Cancers

Attaching a Dipeptide to Fullerene as an Antioxidant Hybrid against DNA Oxidation

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Aggregation Behavior and Antioxidant Properties of Amphiphilic Fullerene C₆₀ Derivatives Cofunctionalized with Cationic and Nonionic Hydrophilic Groups