Dynamics of reduced graphene oxide: synthesis and structural models

Combined Graphene Oxide with 2-Methoxyestradiol for Effective Anticancer Therapy in-vitro Model

Introduction

This article describes the invention of graphene oxide (GO) or reduced graphene oxide (rGO) functionalised with 2-methoxy estradiol. The presence of polar hydroxyl groups enables the binding of 2-ME to GO/rGO through hydrogen bonds with epoxy and hydroxyl groups located on the surface and carbonyl and carboxyl groups located at the edges of graphene flake sheets.

Methods

The patented method of producing the subject of the invention and the research results regarding its anticancer effectiveness via cytotoxicity in an in vivo model (against A375 melanoma and 143B osteosarcoma cells) are described.

Results

It was shown that the inhibition of PTP1B phosphotyrosine phosphatase is one of the mechanisms of action of GO functionalised with 2-ME (GO-2-ME). This is a very important result, considering the fact that 2-ME itself has no inhibitory properties against this phosphatase.

Discussion

Graphene oxide flakes embroidered with 2-methoxyestradiol molecules may be a promising solution, bringing a new and important effect in the form of improving the bioavailability of the therapeutic substance, ie 2-ME. An appropriate dosage of GO-2-ME/rGO-2-ME, in which GO/rGO is a carrier of 2-methoxyestradiol (2-ME), can ensure effective penetration of the active substance through biological boundaries/membranes and controlled modification of cell signalling, ultimately leading to the selective elimination of malignant cells.

Regulation of CC bonds in penta-graphene by oxidative functionalization: a prototype of penta-graphene oxide (PGO)

Penta-graphene (PG) is currently a research hotspot for carbon-based nanomaterials. Herein, we studied the effect of oxidative functionalization on the electric properties of PG by regulating the CC bond. Our results show that the chemical reactivity of the oxidative functionalized PG system is significantly enhanced due to the presence of the dangling bonds, which is achieved at the cost of reduced stability. The oxidative functionalized PG shows enhanced hydrophilicity, which is similar to graphene oxide (GO). More importantly, we found that the adsorption energy decreased gradually with the increase of oxidative functional group coverage, which indicated that hydrogen bonds (H-bonds) between the polarized groups could improve the stability of the oxidative functionalized PG. Finally, we discussed the ratio of carbon and oxygen to hydrogen in oxidative functionalized PG to provide theoretical guidance for experimental characterization. These findings are expected to provide deep insights into understanding the CC regulation in PG and rationally designing and preparing penta-graphene oxide (PGO).

Photocatalytic degradation of organic dyes using reduced graphene oxide (rGO)

Photocatalysts have developed into a successful strategy for degrading synthetic and organic toxins, such as chemicals and dyes, in wastewater. In this study, graphene oxide was reduced at different temperatures and used for degrading indigo carmine and neutral red dyes. The wide surface areas, strong adsorption sites, and oxygen functionalities of reduced graphene oxide (rGO) at 250 °C (rGO-250) produced more photocatalytic degradation efficiency and adsorption percentage. The catalyst dosage, initial dye concentration, solution pH and recyclability were all used to optimize the photocatalytic activity of rGO-250. This research presents a capable nano-adsorbent photocatalyst for the efficient degradation of organic dyes. GO and rGOs were also investigated for carbon dioxide (CO2) absorption properties. Results showed that rGO-250 has better CO2 adsorption properties than other rGOs. Overall, it was observed that rGO-250 has better photocatalytic and CO2 adsorption capabilities compared to graphene oxide reduced at different temperatures.