Jonathan A. Brant scite author profile

Nanomaterial properties differ from those bulk materials of the same composition, allowing them to execute novel activities. A possible downside of these capabilities is harmful interactions with biological systems, with the potential to generate toxicity. An approach to assess the safety of nanomaterials is urgently required. We compared the cellular effects of ambient ultrafine particles with manufactured titanium dioxide (TiO2), carbon black, fullerol, and polystyrene (PS) nanoparticles (NPs). The study was conducted in a phagocytic cell line (RAW 264.7) that is representative of a lung target for NPs. Physicochemical characterization of the NPs showed a dramatic change in their state of aggregation, dispersibility, and charge during transfer from a buffered aqueous solution to cell culture medium. Particles differed with respect to cellular uptake, subcellular localization, and ability to catalyze the production of reactive oxygen species (ROS) under biotic and abiotic conditions. Spontaneous ROS production was compared by using an ROS quencher (furfuryl alcohol) as well as an NADPH peroxidase bioelectrode platform. Among the particles tested, ambient ultrafine particles (UFPs) and cationic PS nanospheres were capable of inducing cellular ROS production, GSH depletion, and toxic oxidative stress. This toxicity involves mitochondrial injury through increased calcium uptake and structural organellar damage. Although active under abiotic conditions, TiO2 and fullerol did not induce toxic oxidative stress. While increased TNF-alpha production could be seen to accompany UFP-induced oxidant injury, cationic PS nanospheres induced mitochondrial damage and cell death without inflammation. In summary, we demonstrate that ROS generation and oxidative stress are a valid test paradigm to compare NP toxicity. Although not all materials have electronic configurations or surface properties to allow spontaneous ROS generation, particle interactions with cellular components are capable of generating oxidative stress.

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Characterizing the Impact of Preparation Method on Fullerene Cluster Structure and Chemistry

Brant

et al. 2006

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We examined the physical and chemical characteristics of colloidal dispersions of fullerene materials (nC60) produced through several solvent exchange processes and through extended mixing in water only. The nC60 produced via the different methods were unique from each other with respect to size, morphology, charge, and hydrophobicity. The greatest dissimilarities were observed between the nC60 produced by extended mixing in water alone and the nC60 produced by solvent exchange processes. The role of the respective solvents in determining the characteristics of the various nC60 were attributed to differences in the solvent-C60 interactions and the presence of the solvent as a residual in the nC60 structure, indicating the significance of the solvent properties in determining the ultimate characteristics of the colloidal fullerene. Thus, fullerene C60 that may become mobilized through natural processes (agitation in water) may behave in dramatically different ways than those produced through more artificial means. These results highlight the difficulties in generalizing nC60 properties, particularly as they vary in potential toxicity considerations.

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Comparison of Electrokinetic Properties of Colloidal Fullerenes (n-C₆₀) Formed Using Two Procedures

Brant

Lecoanet

Hotze

et al. 2005

Environ. Sci. Technol.

227

237

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In this study we report on the electrokinetic behavior of colloidal aggregates of C60fullerenes (n-C60) produced through two different techniques: solvent exchange and extended mixing with water. In the first technique, used to produce colloidal materials in several recent toxicity and transport studies, an organic solvent such as tetrahydrofuran (THF) is used to dissolve the C60 before mixing with water. The second technique is more indicative of conditions that might occur in natural aquatic systems. Both types of n-C60 were observed to be negatively charged under a variety of solution chemistries; however, the n-C60 formed using THF was more strongly charged. We conclude that n-C60 likely acquires charge through charge transfer from the organic solvent (when present) and surface hydrolysis reactions. Nevertheless, C60 is capable of acquiring charge and becoming dispersed as n-C60 in water without the aid of organic solvents, a pathway that may be important in determining the mobility of fullerenes in natural systems. These findings also show that n-C60 made using THF retains a portion of the solvent in the cluster structure, subsequently influencing the characteristics of the n-C60 and possibly requiring a re-interpretation of results from recent studies on n-C60 toxicity using THF-derived materials.

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Aggregation and Deposition Characteristics of Fullerene Nanoparticles in Aqueous Systems

2005

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Assessing short-range membrane–colloid interactions using surface energetics

Brant

2002

380

203

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Hydration and Dispersion of C₆₀ in Aqueous Systems: The Nature of Water−Fullerene Interactions

et al. 2009

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The nature of fullerene-water interactions and the role that they play in the fate of C60 in aqueous systems is poorly understood. This work provides spectroscopic evidence for the surface hydroxylation of the initially hydrophobic C60 molecule when immersed in water. This mechanism appears to be the basis for stabilizing the hydrophilic nC60 aggregates in suspension. It is remarkable that such a chemical transformation and dispersion are achieved under mild conditions that are readily produced in an aquatic environment. This acquired affinity for water is likely to play a subsequent role in the reactivity, mobility, and bioavailability of fullerenes in aqueous media.

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Superhydrophobic dual layer functionalized titanium dioxide/polyvinylidene fluoride- co -hexafluoropropylene (TiO 2 /PH) nanofibrous membrane for high flux membrane distillation

Shahabadi

Rabiee

Seyedi

et al. 2017

Journal of Membrane Science

122

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Fullerol cluster formation in aqueous solutions: Implications for environmental release

Brant

Labille

Robichaud

et al. 2007

Journal of Colloid and Interface Science

104

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Jonathan A. Brant

Comparison of the Abilities of Ambient and Manufactured Nanoparticles To Induce Cellular Toxicity According to an Oxidative Stress Paradigm

Characterizing the Impact of Preparation Method on Fullerene Cluster Structure and Chemistry

Comparison of Electrokinetic Properties of Colloidal Fullerenes (n-C₆₀) Formed Using Two Procedures

Aggregation and Deposition Characteristics of Fullerene Nanoparticles in Aqueous Systems

Assessing short-range membrane–colloid interactions using surface energetics

Hydration and Dispersion of C₆₀ in Aqueous Systems: The Nature of Water−Fullerene Interactions

Superhydrophobic dual layer functionalized titanium dioxide/polyvinylidene fluoride- co -hexafluoropropylene (TiO 2 /PH) nanofibrous membrane for high flux membrane distillation

Fullerol cluster formation in aqueous solutions: Implications for environmental release

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Jonathan A. Brant

Comparison of the Abilities of Ambient and Manufactured Nanoparticles To Induce Cellular Toxicity According to an Oxidative Stress Paradigm

Characterizing the Impact of Preparation Method on Fullerene Cluster Structure and Chemistry

Comparison of Electrokinetic Properties of Colloidal Fullerenes (n-C60) Formed Using Two Procedures

Aggregation and Deposition Characteristics of Fullerene Nanoparticles in Aqueous Systems

Assessing short-range membrane–colloid interactions using surface energetics

Hydration and Dispersion of C60 in Aqueous Systems: The Nature of Water−Fullerene Interactions

Superhydrophobic dual layer functionalized titanium dioxide/polyvinylidene fluoride- co -hexafluoropropylene (TiO 2 /PH) nanofibrous membrane for high flux membrane distillation

Fullerol cluster formation in aqueous solutions: Implications for environmental release

Contact Info

Product

Resources

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Comparison of Electrokinetic Properties of Colloidal Fullerenes (n-C₆₀) Formed Using Two Procedures

Hydration and Dispersion of C₆₀ in Aqueous Systems: The Nature of Water−Fullerene Interactions