Abstract
Graphene and its derivatives are emerging as attractive materials for biomedical applications, including antibacterial, gene delivery, contrast imaging, and anticancer therapy applications. It is of fundamental importance to study the cytotoxicity and biocompatibility of these materials as well as how they interact with the immune system. The present study was conducted to assess the immunotoxicity of graphene oxide (GO) and vanillin-functionalized GO (V-rGO) on THP-1 cells, a human acute monocytic leukemia cell line. The synthesized GO and V-rGO were characterized by using various analytical techniques. Various concentrations of GO and V-rGO showed toxic effects on THP-1 cells such as the loss of cell viability and proliferation in a dose-dependent manner. Cytotoxicity was further demonstrated as an increased level of lactate dehydrogenase (LDH), loss of mitochondrial membrane potential (MMP), decreased level of ATP content, and cell death. Increased levels of reactive oxygen species (ROS) and lipid peroxidation caused redox imbalance in THP-1 cells, leading to increased levels of malondialdehyde (MDA) and decreased levels of anti-oxidants such as glutathione (GSH), glutathione peroxidase (GPX), super oxide dismutase (SOD), and catalase (CAT). Increased generation of ROS and reduced MMP with simultaneous increases in the expression of pro-apoptotic genes and downregulation of anti-apoptotic genes suggest that the mitochondria-mediated pathway is involved in GO and V-rGO-induced apoptosis. Apoptosis was induced consistently with the significant DNA damage caused by increased levels of 8-oxo-dG and upregulation of various key DNA-regulating genes in THP-1 cells, indicating that GO and V-rGO induce cell death through oxidative stress. As a result of these events, GO and V-rGO stimulated the secretion of various cytokines and chemokines, indicating that the graphene materials induced potent inflammatory responses to THP-1 cells. The harshness of V-rGO in all assays tested occurred because of better charge transfer, various carbon to oxygen ratios, and chemical compositions in the rGO. Overall, these findings suggest that it is essential to better understand the parameters governing GO and functionalized GO in immunotoxicity and inflammation. Rational design of safe GO-based formulations for various applications, including nanomedicine, may result in the development of risk management methods for people exposed to graphene and graphene family materials, as these nanoparticles can be used as delivery agents in various biomedical applications.
Highlights
Graphene and graphene family materials (GFM), including graphene oxide (GO), reduced/functionalized graphene oxide, graphene quantum dots, graphene nanoribbons, three-dimensional graphene foam, and graphene nanopores, show immense potential for variety of biomedical applications, such as antibacterial, anticancer, drug delivery, bio-sensing, and bio-imaging applications, because of their excellent physical, chemical, mechanical, and biological properties, large surface area, ease of surface functionalization, and significant colloidal stability in aqueous media compared to pristine graphene [1,2,3,4]
Graphene and graphene derivatives are increasingly utilized in biomedical applications because of their unique properties, including large surface area and mechanical, physical, chemical, and biological properties
We focused on the differential effect of GO and the biomolecule V-reduced/functionalized graphene oxide (rGO) with an average size of 100 nm by using the same starting material in THP-1 cells
Summary
Graphene and graphene family materials (GFM), including graphene oxide (GO), reduced/functionalized graphene oxide (rGO), graphene quantum dots, graphene nanoribbons, three-dimensional graphene foam, and graphene nanopores, show immense potential for variety of biomedical applications, such as antibacterial, anticancer, drug delivery, bio-sensing, and bio-imaging applications, because of their excellent physical, chemical, mechanical, and biological properties, large surface area, ease of surface functionalization, and significant colloidal stability in aqueous media compared to pristine graphene [1,2,3,4]. GO and rGO have different physical and chemical properties such as solubility and dispensability, lateral dimension, sheet size, and oxidation and reduction degrees. The synthesis method determines the size, morphology, solubility, toxicity, and biocompatibility of graphene. Nanosized graphene materials must be synthesized for biomedical applications, such as to cause either toxicity or biocompatibility. Gurunathan and coworkers demonstrated the different biological properties of GO and rGO in different types of bacteria as well as cancer and non-cancer cells [13,14,15,16,17]. Studies by Chatterjee et al, [18] demonstrated the toxic effects of GO and rGO with different hydrophilicity/hydrophobicity levels on HepG2 cells. GO and rGO, which differ in size, showed different toxicities towards glioblastoma cell lines [19]
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