The mechanisms of action of water-soluble aminohexanoic and malonic adducts of fullerene C60 with hexamethonium on model lipid membranes.

In an attempt to understand the possibility of applications of the fullerene-based systems for transporting various polar compounds like hexamethonium through the blood-brain barrier, we studied the influence of a series of derivatives of fullerene C60 in the form of salts with hexamethonium bis-anion, namely the adducts of fullerenols with 6-aminohexanoic acid (IEM-2197), and two bis-adduct malonic acid derivatives of fullerene with addents bound in two hemispheres (IEM-2143) and in equatorial positions (IEM-2144), on model membranes. We showed that IEM-2197 induced the disintegration of the bilayers composed of DOPC at the concentrations more than 2 mg/ml. IEM-2144 and IEM-2143-induced ion-permeable pores at concentrations of 0.3 and 0.02 mg/ml, respectively; herewith, IEM-2143 was characterized by the greater efficiency than IEM-2144. IEM-2197 did not significantly affect the phase behavior of DPPC, while the melting temperature significantly decreased with addition of IEM-2144 and IEM-2143. The increase in the half-width of the main transition peaks by more than 2.0 °C in the presence of IEM-2144 and IEM-2143 was observed, along with the pronounced peak deconvolution. We proposed that the immersion of IEM-2144 and IEM-2143 into the polar region of the DOPC or DPPC bilayers led to an increase in the relative mobility of tails and formation of ion-permeable defects. IEM-2197 demonstrated the more pronounced effects on the melting and ion permeability of PG- and PS-containing bilayers compared to PC-enriched membranes. These results indicated that IEM-2197 preferentially interacts with the negatively charged lipids compared to neutral species.

Enhanced brain penetration of hexamethonium in complexes with derivatives of fullerene C60.

The present report describes development of hexamethonium complexes based on fullerene C60. Hexamethonium has a limited penetration into CNS and therefore can antagonize central effects of nicotine only when given at high doses. In the present studies conducted in laboratory rodents, intraperitoneal administration of hexamethonium-fullerene complexes blocked effects of nicotine (convulsions and locomotor stimulation). When compared to equimolar doses of hexamethonium, complexes of hexamethonium with derivatives of fullerene C60 were 40 times more potent indicating an enhanced ability to interact with central nicotine receptors. Thus, fullerene C60 derivatives should be explored further as potential carrier systems for polar drug delivery into CNS.

The biodegradation of fullerene C60 by myeloperoxidase.

It is shown for the first time that the mammalian enzymes can cause the degradation of the C60 fullerene molecules. This biodegradation is caused by the action of а hypochlorite generated neutrophil enzyme myeloperoxidase of fullerene molecule and leads to the loss of the topology of the fullerene core.

[Effect of different water-soluble forms of the fullerene C60 on the metabolic activity and ultra-structure of cells in culture].

In view of contradictory data on the toxicity of fullerenes for live organisms we studied the effect of water-soluble complexes of C60 with N-polyvivyl-pirrolidone (C60/PVP) and gamma-cyclodextrine (C60/gamma-CD) on MA-104 cells in culture. Both complexes proved to be non-toxic for cultured cells in the dark in wide range of concentrations. Both complexes provoke changes of cellular ultra-structure which reflect the enhancement of metabolic activity. At the same time only the exposition with the complex C60/PVP leads to the essential growth of number and size of mitochondria. However, the effect of two studied water-soluble forms of C60 under intensive UV-irradiation of cells proved to be opposite: C60/PVP had a cyto-protective action while C60/gamma-CD caused a significant growth of photo-toxicity. Possible reasons of the differences in the action of different forms of C60 on living organisms are discussed.

[Effect of polymer carrier origin and physical state on fullerene C60 phototoxicity in vitro].

Biological effects of water-soluble inclusion complexes of fullerene C60 with poly(vinyl pyrrolidone) (C60/PVP) and gamma-cyclodextrin (C60/g-CD) as well as solid C60 (C60-coated surface) on cell viability have been studied in vitro. It is established that both inclusion complexes (in a broad range of concentrations) and solid fullerene coatings are nontoxic in the dark for the cell of all lines tested. In contrast, under intense UV illumination, the C60/PVP complex reliably protected test cells from the UV radiation damage, whereas the C60/g-CD and fullerene-coated surface exhibited pronounced phototoxicity. Moreover, solid fullerene caused a photodynamic effect under irradiation with both UV and visible light. The radiation damage could be blocked by some antioxidants (e.g., hypoxen) and singlet-oxygen scavenger (sodium azide). This is evidence for the participation of 1O2 in phototoxicity manifestations. The results indicate that the biological properties of fullerene C60 in vitro depend on its aggregate state, form of solubilization, and, probably, the nature of solubilizing medium.