In vitro evaluation of the intensifying photodynamic effect due to the presence of plasmonic hollow gold nanoshells loaded with methylene blue on breast and melanoma cancer cells.

BACKGROUND: Hypoxia is one of the most important limiting factors in photodynamic therapy that can reduce the effectiveness of this treatment. By designing a nanocomplex of plasmonic nanoparticles and photosensitizers with similar optical properties, the rate of free oxygen radical production can be increased and the efficiency of photodynamic therapy can be improved. in this study, we tried to use the outstanding capacities of hollow gold nanoshells (HGNSs) as a plasmonic nanocarrier of methylene blue (MB) to improve the performance of photodynamic therapy. METHODS AND MATERIAL: After synthesis and optimization of hollow gold nanoshells loaded with Methylene blue (HGNSs-PEG-MB), the characteristics of MB, HGNSs, HGNSs-PEG, HGNSs-PEG-MB, and their toxicity at different concentrations on the cell lines was determined. After determining of optimum concentration of nano agents, irradiation of cell was performed with non-coherent of light source with 670 nm wavelength and an intensity of 14.9 mW/cm2. Twenty-four hours after irradiation, an MTT assay was used to determine cell survival percentage. To compare the results, we defined different indexes such as treatment efficiency (TE), synergism ratio (SYN), and the amount of exposure required for 50% cell death (ED50). All the tests were repeated at least four times on the DFW and MCF-7 cancer cell lines. RESULTS: For combination therapies with Lumacare irradiated HGNSs-PEG-MB, the UC index was less than one for all concentrations (P < 0.05). Also, the IC50 index for this nanostructure in non-irradiated conditions and less than 9 min irradiation time was lower than other treatment groups (P < 0.05). ED50 amounts for HGNSs-PEG-MB in all concentrations were greater than the other groups. TE Index was also reported to be greater than 1 in all irradiation conditions and concentrations. CONCLUSION: In this study, HGNSs-PEG in the role of nanocarriers for methylene Blue was used. The results showed that irradiated HGNSs-PEG-MB by 670 nm light severely induced cell death and greatly improved the efficiency of photodynamic therapy in melanoma and breast cancer cells.

Accompanying photocytotoxic activity of gold nanoechinus and zinc phthalocyanine on cancerous cell lines.

BACKGROUND: Near-infrared triggered photodynamic therapy (NIR-PDT) has been introduced as a relatively deep tumor treatment modality. The gold Nanoechinus (Au NE) is a rare type of nanostructures that act as a transducer to change NIR wavelength to ultraviolet (UV) and visible lights. During the photodynamic process, Au nanoechinus (Au NE) converts the irradiation of 980 nm to 674 nm which is absorbed by Zn(II) Phthalocyanine tetrasulfonic acid (ZnPcS). In this study the cooperation effect of Au NE and ZnPcS in PDT on MCF7 and Hela cells was investigated. METHODS: Cytotoxicity and phototoxicity of the composition having different concentrations of Au NE and ZnPcS upon irradiation of 980 nm NIR light were evaluated against MCF7 and Hela cells after two different incubation times and irradiating with two different power densities of laser. RESULTS: Among different experimental groups, in MCF7 cells, which were incubated for 48 h with 50 µg/mL Au NE+2µM ZnPcS and were treated by 980 nm laser with a power density of 200 mW cm-2 for 15 and 30 min, 48 and 38% cell viability were recorded. No appreciable result was observed due to PDT of Hela cells. CONCLUSIONS: Comparing to other PDT modalities against MCF7 cells, NIR-PDT procedure suggested in this study with the synergistic effect of Au NE and ZnPcS could be a secure promising modality in the treatment of deep-seated tumors. Carefully increasing the power density and ambient temperature, to the extent of skin tolerance threshold value, seems to be efficient in the treatment of Hela cells.

The effect of UV radiation in the presence of TiO2-NPs on Leishmania major promastigotes.

BACKGROUND: Cutaneous leishmaniasis is a parasitic disease, which is difficult to treat due to high drug resistance and adverse side effects. Photodynamic therapy by ultraviolet radiation using materials with high photocatalytic features like titanium dioxide nanoparticles (TiO2-NPs) is an emerging treatment for this disease. In this study, TiO2-NPs with ultraviolet (UV) radiation were administered as photodynamic therapy against Leishmania Major (LM) promastigotes. METHODS: Two forms of TiO2 viz. including Anatase and Rutile were administered in two UV ranges< UVA and UVB for different time periods (30 and 60 min). Finally, 24 and 48 h after incubation, the MTS test was performed and cell survival percentage was calculated. RESULTS: The mean size of Anatase and Rutile-NPs is approximately 32.5 and 50.9 nm respectively by DLS and FE-SEM, and crystal phase is emphasized by XRD. The combined treatment of LM with TiO2-NPs and UV has significant effects on LM promastigotes, which vary depending on NP and UV types. The synergistic effect was anticipated in the groups irradiated by UV-B in the presence of Rutile NPs. CONCLUSION: The combined treatment with UV- radiation and TiO2-NPs can be effective in killing the promastigotes of Leishmania major. The proper concentration of NPs and the type of UV-radiation must be taken into consideration. The results suggest improved treatment methods, after proper in vivo studies.

Silver nanoparticles and electroporation: Their combinational effect on Leishmania major.

Leishmaniasis is an emerging and uncontrolled disease. The use of routine drugs has been limited due to proven side effects and drug resistance. Interestingly, novel approaches such as nanotechnology have been applied as a therapeutic modality. Silver nanoparticles have shown antileishmanial effects but because of their nonspecific and toxic effects on normal cells, their use has been limited. On the other hand, it has been demonstrated that electric pulses induce electropores on cell membranes resulting in higher entrance of certain molecules into cells. There is a hypothesis proposing that use of electroporation and silver nanoparticles simultaneously can induce greater accumulation of particles in infected cells, besides higher toxicity. In this study, after applying electric pulses with different concentrations of silver nanoparticles (SNPs), cell survival rate was determined by standard viability assays. On the basis of these data, 2 µg/ml of SNPs and 700 V/cm with 100 µs duration of electroporation were selected as the non-lethal condition. Promastigotes and infected macrophage cells received both treatments and the survival percentage and Infection Index were calculated. In parasites and cells receiving both treatments, higher toxicity was observed in comparison to each treatment given individually, showing a synergic effect on promastigotes. Therefore, application of electric pulses could overcome limitations in using the antileishmanial properties of silver nanoparticles.