An overview of graphene materials: Properties, applications and toxicity on aquatic environments

Marchi, Lucia De; Pretti, Carlo; Gabriel, Bárbara; Marques, Paula A.A.P.; Freitas, Rosa; Neto, Victor

doi:10.1016/j.scitotenv.2018.03.132

Cited by 143 publications

(68 citation statements)

References 159 publications

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“…Although in this review, we have restricted our observations on embryos, larvae, and adult fish, several fish cell lines, including the hepatocellular carcinoma cell line PLHC-1 (derived from topminnow fish, Poeciliopsis lucida ) (Lammel and Navas, 2014), cardiac cell lines (SICH) of Catla catla (Xing et al 2016) and bluegill sunfish cells (BF-2) (Srikanth et al 2018) have been used for the evaluation of GPN toxicity (GO and RGO for SICH cell lines and PLHC1 and BF-2 for GO). From the available literature we reviewed we found that the size, shape, surface properties and chemistry, concentration, agglomeration, dose, and method of preparation of GPN, are the major determinants that affect the various biological activities in zebrafish (Chen et al 2015a, b; 2016; Zhu et al, 2015; Ren et al 2016; Lu et al 2017; Zhang et al 2017a; Zhang et al 2017b; De Marchi et al 2018). As mentioned above, presence of NOM, thiol, or other compounds such as polyethylene glycol in the media or coating/labeling of GPN (functionalization) by fluorescence emitters or others, were also able to substantially modulate the toxic effects of GPN (Chen et al 2015b; Mu et al 2015;2016; Clemente et al 2017; Oh et al 2017).…”

Section: Discussion and Perspectivesmentioning

confidence: 99%

“…Because of the release of considerable amounts nanoparticles into the environment almost every day, and for the ERC guidelines, investigations on the effect of GPN on aquatic organisms are critical. Some studies have found that GPN exhibited high toxicity to marine and freshwater algae, damaged organelles, enhanced ROS generation, induced nutrition depletion, and reduced photosynthetic pigment concentration (Hazeem et al 2016; Zhao et al 2017; De Marchi et al, 2018). We have also documented from the published literature included in this review that GPN was able to penetrate the chorion (both zebrafish and Japanese medaka) and reach the embryonic body in fish during development and causing DNA damage.…”

Section: Discussion and Perspectivesmentioning

confidence: 99%

“…Because aggregation or agglomeration of GO can change its size, effective surface area, and other physicochemical properties, it may modulate its toxicity to aquatic organisms including fish. Although several excellent reviews on the toxic effects of GPN are currently available on aquatic organisms (Zhao et al 2014; De Marchi et al 2018), to our knowledge, a comprehensive review focusing on fish is lacking. A significant impediment for writing a comprehensive review on GPN toxicity targeting fish is the lack of extensive literature in this area.…”

Section: Introductionmentioning

confidence: 99%

“…A significant impediment for writing a comprehensive review on GPN toxicity targeting fish is the lack of extensive literature in this area. In most of the reviews on GPN toxicity that include fish, the effects were briefly summarized either as a separate section or in a comparative approach with other organisms (De Marchi et al 2018). Moreover, the possible mechanisms of interaction of GPN with the biological systems in fish are not well eludicated.…”

Section: Introductionmentioning

confidence: 99%

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Graphene-Based Nanomaterials Toxicity in Fish

Dasmahapatra

Dasari

Tchounwou

2018

Reviews of Environmental Contamination and Toxicology

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Due to their unique physicochemical properties, graphene-based nanoparticles (GPN) constitute one of the most promising types of nanomaterials used in biomedical research. GPN have been used as polymeric conduits for nerve regeneration, carriers for targeted drug delivery, and in the treatment of cancer via photo-thermal therapy. Moreover, they have been used as tracers to study the distribution of bioactive compounds used in healthcare. Due to their extensive use, GPN released into the environment would probably pose a threat to living organisms and ultimately to human health. Their accumulation in the aquatic environment creates problems to aquatic habitats as well as to food chains. Until now the potential toxic effects of GPN are not properly understood. Despite agglomeration and long persistence in the environment, GPN are able to cross the cellular barriers successfully, entered into the cells and able to interact with all most all the cellular sites including the plasma membrane, cytoplasmic organelles, and nucleus. Their interaction with DNA creates more potential threats to both the genome and epigenome. In this brief review, we focused on fish, mainly zebrafish (Danio rerio), as a potential target animal of GPN toxicity in the aquatic ecosystem.

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Section: Discussion and Perspectivesmentioning

confidence: 99%

Section: Discussion and Perspectivesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Graphene-Based Nanomaterials Toxicity in Fish

Dasmahapatra

Dasari

Tchounwou

2018

Reviews of Environmental Contamination and Toxicology

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confidence: 99%

Synthesis, Study and Applications of Graphene Materials

Gerasimova¹,

Smolsky²,

Melezhik³

et al. 2019

Proceedings of the 4th World Congress on Recent Advances in Nanotechnology

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Extended AbstractDifferent graphene materials attract great attention of scientists and technologists all over the world. Such materials are used in electronics, adsorption, catalysis and photocatalysis, sensors, batteries, composite materials, medicine, etc [1][2][3][4][5][6].It is shown herein that the interaction of natural graphite with solutions of (NH4)2S2O8, K2S2O8, H2S2O8 or H2SO5 in sulphuric acid results in the formation of peroxosulfate graphite intercalation compounds that are able to expand at low temperature (20-60 o C). These expanded graphite intercalation compounds (EGICs) are composed of weakly bonded graphene nanoplatelets (GNPs), which can be easily exfoliated via different methods. Ultrasonic exfoliation is the most straightforward technique. Depending on sonication conditions, few-or multi-layered GNPs can be obtained (with or without using surfactants, respectively). They contain surface oxygen groups. The other way of EGIC exfoliation is through mechanical-chemical treatment.To obtain GNPs with non-oxidized surface, EGICs were processed using ammonia. Due to the highly exothermic reaction of acidic EGIC with ammonia, the energy evolved ensures further exfoliation of graphene layers with simultaneous reduction of oxygen groups. Thus, the ultrasonic treatment, which is usually the bottle-neck restricting the productivity of the process, can be excluded. In this regard, spontaneous exfoliation, induced directly by the chemical energy, is very favorable for establishing large-scale industrial production of graphene materials. Multi-layered GNPs obtained through the chemical exfoliation possess high electrical conductivity in different formulations with organic and inorganic binders. GNPs obtained through the ammonia treatment method are highly electroconductive in polymeric compositions. For instance, polymer materials containing 10-20 wt.% ammonia-GNPs possess a conductivity of 5-15 S/cm, which exceeds that of any other electroconductive carbon filler.Considering the aforementioned, methods for superficial modification of GNPs, which can allow improving their compatibility with organic polymers and the stability of their dispersions in solvents, were developed herein. The first method includes treating oxygen-containing GNPs with a phenol-formaldehyde resin (PFR); PFR-modified GNPs possess good solubility in water and epoxy resin. The second one involves the modification of GNPs using aminocumulene. High solubility (up to several wt.%) of materials obtained in water is an interesting peculiarity of these modification methods, which allows fabrication of films by drying aqueous dispersions.Moreover, graphene/ferrites nanocomposites were synthesised. For this purpose, magnetite and cobalt ferrite nanoparticles were deposited on the GNP surface from aqueous solutions of iron and cobalt salts at appropriate pH and temperature mode.The surface of GNPs can also be modified with nanoporous carbon. To perform such a synthesis, GNPs were modified with the PFR, then mixed with excess PFR, cured, carbon...

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Toward the Application of Graphene for Combating Marine Biofouling

Jin

Tian

Bing

et al. 2020

Advanced Sustainable Systems

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The discovery of graphene has brought great innovations to materials science. Since tributyltin antifouling coatings were banned worldwide in 2008, the development of green antifouling coatings has become necessary. Recently, novel graphene‐related antifouling coatings have been the focus of many studies due to their enhanced mechanical strength, excellent antifouling capabilities, and environmental friendliness. This review starts by introducing the basic antifouling mechanisms of graphene nanosheets and the possible antifouling mechanisms when graphene is incorporated into coatings. Subsequently, the progress and existing problems regarding the application of graphene in the prevention of marine biofouling are discussed. Specifically, this review focuses on six graphene‐related antifouling coatings, including pure graphene film, nanohybrids, foul release coatings, photocatalytic nanocomposites, desalination membranes, and materials for uranium enrichment. The fabrication, antifouling properties, working mechanisms, and future development of graphene‐related antifouling coatings are highlighted. In addition, the potential environmental risk of using graphene materials in preventing marine biofouling is explained, and the basic requirements for designing an environmentally friendly graphene‐related antifouling coating are discussed. Finally, the prospect of applying graphene materials for combating marine biofouling is presented. This review aims to aid in improving the design of graphene‐related green antifouling coatings.

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An overview of graphene materials: Properties, applications and toxicity on aquatic environments

Cited by 143 publications

References 159 publications

Graphene-Based Nanomaterials Toxicity in Fish

Graphene-Based Nanomaterials Toxicity in Fish

Synthesis, Study and Applications of Graphene Materials

Toward the Application of Graphene for Combating Marine Biofouling

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