Stable, concentrated, biocompatible, and defect-free graphene dispersions with positive charge

The outstanding properties of graphene offer high potential for biomedical applications. In this framework, positively charged nanomaterials show better interactions with the biological environment, hence there is strong interest in the production of positively charged graphene nanosheets. Currently...

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Hauptverfasser:	Shin, Yuyoung, Vranic, Sandra, Just-Baringo, Xavier, Gali, Sai Manoj, Kisby, Thomas, Chen, Yingxian, Gkoutzidou, Alexandra, Prestat, Eric, Beljonne, David, Larrosa, Igor, Kostarelos, Kostas, Casiraghi, Cinzia
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Sprache:	eng
Schlagworte:	Biological environments Biomedical applications Colloidal Stability Graphene dispersions Graphene nanosheets Graphite Molecular dynamics simulations Nanoscale interactions Nanostructures Pyrene derivatives Water
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creator	Shin, Yuyoung Vranic, Sandra Just-Baringo, Xavier Gali, Sai Manoj Kisby, Thomas Chen, Yingxian Gkoutzidou, Alexandra Prestat, Eric Beljonne, David Larrosa, Igor Kostarelos, Kostas Casiraghi, Cinzia
description	The outstanding properties of graphene offer high potential for biomedical applications. In this framework, positively charged nanomaterials show better interactions with the biological environment, hence there is strong interest in the production of positively charged graphene nanosheets. Currently, production of cationic graphene is either time consuming or producing dispersions with poor stability, which strongly limit their use in the biomedical field. In this study, we made a family of new cationic pyrenes, and have used them to successfully produce water-based, highly concentrated, stable, and defect-free graphene dispersions with positive charge. The use of different pyrene derivatives as well as molecular dynamics simulations allowed us to get insights on the nanoscale interactions required to achieve efficient exfoliation and stabilisation. The cationic graphene dispersions show outstanding biocompatibility and cellular uptake as well as exceptional colloidal stability in the biological medium, making this material extremely attractive for biomedical applications.
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In this framework, positively charged nanomaterials show better interactions with the biological environment, hence there is strong interest in the production of positively charged graphene nanosheets. Currently, production of cationic graphene is either time consuming or producing dispersions with poor stability, which strongly limit their use in the biomedical field. In this study, we made a family of new cationic pyrenes, and have used them to successfully produce water-based, highly concentrated, stable, and defect-free graphene dispersions with positive charge. The use of different pyrene derivatives as well as molecular dynamics simulations allowed us to get insights on the nanoscale interactions required to achieve efficient exfoliation and stabilisation. The cationic graphene dispersions show outstanding biocompatibility and cellular uptake as well as exceptional colloidal stability in the biological medium, making this material extremely attractive for biomedical applications.</description><language>eng</language><subject>Biological environments ; Biomedical applications ; Colloidal Stability ; Graphene dispersions ; Graphene nanosheets ; Graphite ; Molecular dynamics simulations ; Nanoscale interactions ; Nanostructures ; Pyrene derivatives ; Water</subject><creationdate>2020</creationdate><rights>open access Aquest document està subjecte a una llicència d'ús Creative Commons. 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subjects	Biological environments Biomedical applications Colloidal Stability Graphene dispersions Graphene nanosheets Graphite Molecular dynamics simulations Nanoscale interactions Nanostructures Pyrene derivatives Water
title	Stable, concentrated, biocompatible, and defect-free graphene dispersions with positive charge
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