Long Term Influence of Carbon Nanoparticles on Health and Liver Status in Rats.

Due to their excellent biocompatibility, carbon nanoparticles have been widely investigated for prospective biomedical applications. However, their impact on an organism with prolonged exposure is still not well understood. Here, we performed an experiment investigating diamond, graphene oxide and graphite nanoparticles, which were repeatedly administrated intraperitoneally into Wistar rats for four weeks. Some of the animals was sacrificed after the last injection, whereas the rest were sacrificed twelve weeks after the last exposure. We evaluated blood morphology and biochemistry, as well as the redox and inflammatory state of the liver. The results show the retention of nanoparticles within the peritoneal cavity in the form of prominent aggregates in proximity to the injection site, as well as the presence of some nanoparticles in the mesentery. Small aggregates were also visible in the liver serosa, suggesting possible transportation to the liver. However, none of the tested nanoparticles affected the health of animals. This lack of toxic effect may suggest the potential applicability of nanoparticles as drug carriers for local therapies, ensuring accumulation and slow release of drugs into a targeted tissue without harmful systemic side effects.

Nanodiamond-based chemotherapy and imaging.

The advent of cancer nanomedicine has forged new pathways for the enhanced imaging and treatment of a broad range of cancers using new classes of materials. Among the many platforms being developed for drug delivery and imaging, nanodiamonds (NDs) possess several important attributes that may be beneficial toward improving the efficacy and safety of cancer nanomedicine applications. These include the uniquely faceted surfaces of the ND particles that result in electrostatic properties that mediate enhanced interactions with water and loaded therapeutic compounds, scalable processing and synthesis parameters, versatility as platform carriers, and a spectrum of other characteristics. In addition, comprehensive in vitro and in vivo studies have demonstrated that NDs are well tolerated. This chapter will examine several recent studies that have harnessed the ND agent as a foundation for both systemic and localized drug delivery, as well as the marked improvements in magnetic resonance imaging efficiency that has been observed following ND-contrast agent conjugation. In addition, insight into the important steps toward bringing the ND translational pathway to the clinic will be discussed.

Analysis of the cytotoxicity of carbon-based nanoparticles, diamond and graphite, in human glioblastoma and hepatoma cell lines.

Nanoparticles have attracted a great deal of attention as carriers for drug delivery to cancer cells. However, reports on their potential cytotoxicity raise questions of their safety and this matter needs attentive consideration. In this paper, for the first time, the cytotoxic effects of two carbon based nanoparticles, diamond and graphite, on glioblastoma and hepatoma cells were compared. First, we confirmed previous results that diamond nanoparticles are practically nontoxic. Second, graphite nanoparticles exhibited a negative impact on glioblastoma, but not on hepatoma cells. The studied carbon nanoparticles could be a potentially useful tool for therapeutics delivery to the brain tissue with minimal side effects on the hepatocytes. Furthermore, we showed the influence of the nanoparticles on the stable, fluorescently labeled tumor cell lines and concluded that the labeled cells are suitable for drug cytotoxicity tests.

Nano-nutrition of chicken embryos. The effect of in ovo administration of diamond nanoparticles and L-glutamine on molecular responses in chicken embryo pectoral muscles.

It has been demonstrated that the content of certain amino acids in eggs is not sufficient to fully support embryonic development. One possibility to supply the embryo with extra nutrients and energy is in ovo administration of nutrients. Nanoparticles of diamond are highly biocompatible non-toxic carbonic structures, and we hypothesized that bio-complexes of diamond nanoparticles with L-glutamine may affect molecular responses in breast muscle. The objective of the investigation was to evaluate the effect of diamond nanoparticle (ND) and L-glutamine (Gln) on expression of growth and differentiation factors of chicken embryo pectoral muscles. ND, Gln, and Gln/ND solutions (50 mg/L) were injected into fertilized broiler chicken eggs at the beginning of embryogenesis. Muscle tissue was dissected at day 20 of incubation and analysed for gene expression of FGF2, VEGF-A, and MyoD1. ND and especially Gln/ND up-regulated expression of genes related to muscle cell proliferation (FGF2) and differentiation (MyoD1). Furthermore, the ratio between FGF2 and MyoD1 was highest in the Gln/ND group. At the end of embryogenesis, Gln/ND enhanced both proliferation and differentiation of pectoral muscle cells and differentiation dominated over proliferation. These preliminary results suggest that the bio-complex of glutamine and diamond nanoparticles may accelerate growth and maturation of muscle cells.

[The effect of modified nano-diamonds of detonation synthesis on the protein fractions of human blood].

It is established that the modified nano-diamonds of detonation synthesis are able to bind serum proteins of human blood. The relative selectivity is established concerning the effect of modified nano-diamonds of detonation synthesis on beta2- and gamma-globulin fractions of serum. The evidence of concentration dependence of effect of modified nano-diamonds of detonation synthesis from serum proteins is established. The study results make it possible to consider modified nano-diamonds of detonation synthesis as a potential sorbent in technologies of hemodialysis, plasmapheresis, isolation of blood proteins and as a foundation for development of new systems of laboratory diagnostic.

Biodistribution and toxicity of nanodiamonds in mice after intratracheal instillation.

Nanodiamonds (NDs) are receiving increasing attention in materials science and nanotechnology-based industries for a large variety of applications, including protein immobilization, biosensors, therapeutic molecule delivery, and bioimaging. However, limited information is known about their biokinetic behavior and toxicity in vivo. In this article, we investigated the biodistribution of NDs using radiotracer techniques and evaluated its acute toxicity in Kun Ming mice after intratracheal instillation. The biodistribution showed that, besides having the highest retention in the lung, NDs were distributed mainly in the spleen, liver, bone and heart. An analysis of histological morphology and biochemical parameters indicated that NDs could induce dose-dependent toxicity to the lung, liver, kidney and blood. This work provided fundamental data for understanding the biodistribution of NDs and will provide guidance for further study of their toxicity.