Surface Area of Graphene Governs Its Neurotoxicity

Graphene is the newest form of elemental carbon and it is becoming rapidly a potential candidate in the framework of nano‐bio research. Many reports confirm the successful use of graphene‐based materials as carriers of anticancer drugs having relatively high loading capacities compared with other nanocarriers. Here, the outcomes of a systematic study of the adsorption behavior of FDA approved PtII drugs cisplatin, oxaliplatin, and carboplatin on surface models of pristine, holey, and nitrogen‐doped holey graphene are reported. DFT investigations in water solvent have been carried out considering several initial orientations of the drugs with respect to the surfaces. Adsorption free energies, calculated including basis set superposition error (BSSE) corrections, result to be significantly negative for many of the drug@carrier adducts indicating that tested layers could be used as potential carriers for the delivery of anticancer PtII drugs. The reduced density gradient (RDG) analysis allows to show that many kinds of non‐covalent interactions, including canonical H‐bond, are responsible for the stabilization of the formed adducts.

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Electroconductive Gelatin/Alginate/ Graphene Hydrogel Based Scaffold for Neural Tissue Repair

Madaninasab,

Mohammadi,

Labbaf

2024

Macro Materials & Eng

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A composite polymeric scaffold of gelatin/alginate /graphene is fabricated through freeze‐drying technique. Initially, a hydrogel system comprised of gelatin/alginate (1:1) is prepared, and then the effect of different amounts of graphene carboxyl nanosheets (1,1.5, 2, and 2.5 wt.%) on the resultant structural properties are thoroughly evaluated. The swelling ratio, biodegradability, electrical and mechanical properties of bio‐composite hydrogels are controlled by manipulating the concentration of graphene‐COOH. The significant increase in the electrical conductivity is observed with the addition of 2.5% graphene‐COOH, and the electrical conductivity increased from 8.525 × 10−7 ± 0.01 S cm−1 to 7.644 × 10−4 ± 0.04 S cm−1. Also, the biocomposite hydrogels exhibited compressive and tensile strength ranging from 25 to 382 KPa and 11.4 to 148 KPa with an increase in the concentration of graphene‐COOH. The simplicity, low cost, tunable mechanical properties, and optimal electrical conductivity of the hydrogel system presented in this study highlight its potential as nerve tissue replacement.

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Surface Area of Graphene Governs Its Neurotoxicity

Cited by 9 publications

References 80 publications

Recent progress in graphene and its derived hybrid materials for high-performance supercapacitor electrode applications

Recent progress in graphene and its derived hybrid materials for high-performance supercapacitor electrode applications

Computational assessment of the use of graphene‐based nanosheets as Pt^II chemotherapeutics delivery systems

Electroconductive Gelatin/Alginate/ Graphene Hydrogel Based Scaffold for Neural Tissue Repair

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Surface Area of Graphene Governs Its Neurotoxicity

Cited by 9 publications

References 80 publications

Recent progress in graphene and its derived hybrid materials for high-performance supercapacitor electrode applications

Recent progress in graphene and its derived hybrid materials for high-performance supercapacitor electrode applications

Computational assessment of the use of graphene‐based nanosheets as PtII chemotherapeutics delivery systems

Electroconductive Gelatin/Alginate/ Graphene Hydrogel Based Scaffold for Neural Tissue Repair

Contact Info

Product

Resources

About

Computational assessment of the use of graphene‐based nanosheets as Pt^II chemotherapeutics delivery systems