Vesna Benković

Radioprotective effects of propolis and quercetin in γ-irradiated mice evaluated by the alkaline comet assay

The radioprotective effects of ethanolic extract of propolis (EEP) and quercetin on the white blood cells of the whole-body irradiated CBA mice were investigated. Irradiation was performed using a gamma-ray source ((60)Co), and absorbed dose was 9 Gy. The efficiency of test components was evaluated when given intraperitoneally (ip) at a dose of 100 mg kg(-1) for 3 consecutive days before and/or after irradiation. Moreover, possible genotoxic effects of test components were also assessed on non-irradiated animals. For each experimental group leukocyte count was determined and the primary DNA damage in leukocytes was assessed using the alkaline comet assay. The higher efficiency of EEP and quercetin was observed when given preventively. The results suggest that propolis and quercetin given to mice before irradiation protect their white blood cells from lethal effects of irradiation and diminish primary DNA damage as confirmed by the alkaline comet assay. Positive results obtained on gamma-irradiated mice given EEP and quercetin, complementary with our earlier observations on survival of irradiated mice, indicate that these compounds could be considered effective non-toxic radioprotectors. The exact mechanisms of radioprotection by these compounds and their effects on DNA repair processes are still to be elucidated.

Radioprotective Effects of Quercetin and Ethanolic Extract of Propolis in Gamma-Irradiated Mice

Radioprotective Effects of Quercetin and Ethanolic Extract of Propolis in Gamma-Irradiated Mice The aim of this study was to assess radioprotective effects of quercetin and the ethanolic extract of propolis (EEP) in CBA mice exposed to a single radiation dose 4 Gy (60Co). The mice were treated with 100 mg kg-1 quercetin or EEP a day for three consecutive days either before (pre-treatment) or after gamma-irradiation (therapy). Leukocyte count was determined in blood drawn from the tail vein, and DNA damage in leukocytes was assessed using the alkaline comet assay. Genotoxic effects of the test compunds were also evaluated in non-irradiated mice. The levels of radioprotection provided by both test compounds were compared with those established in mice that were given chemical radioprotector S-(2-Aminoethy1)isothiouronium bromide hydrobromide (AET). Mice that received pre-treatment were less sensitive to irradiation. Mice given the post-irradiation therapy showed a slight but not significant increase in total leukocyte count over irradiated negative control. Quercetin showed better protective properties than EEP in both pre-treatment and therapy, and activated a higher number of leukocytes in non-irradiated mice. The alkaline comet assay suggests that both natural compounds, especially when given as pre-treatment, protect against primary leukocyte DNA damage in mice. At tested concentrations, EEP and quercetin were not genotoxic to non-irradiated mice. AET, however, caused a slight but not significant increase in DNA damage. Although the results of this study show the radioprotective potential of the test compounds, further investigation is needed to clarify the underlying protection mechanisms. Primjena alkalnog kometnog testa u istraživanju radioprotektivnih učinaka alkoholnog ekstrakta propolisa i kvercetina na miševima ozračenim gama-zračenjem

Evaluation of radioprotective effects of propolis and its flavonoid constituents: in vitro study on human white blood cells.

This in vitro study aimed to evaluate the possible radioprotective effects of the natural substances WSDP, caffeic acid, chrysin and naringin on γ‐irradiated human white blood cells. The effectiveness of tested compounds was evaluated using the alkaline comet assay, the analysis of structural chromosome aberration and the cytokinesis‐block micronucleus assay. The results obtained by the alkaline comet study indicate favourable toxicity profiles of propolis and its polyphenolic components, and confirmed the radioprotective abilities comparable to the chemical radioprotector AET. WSDP and its polyphenolic components were able to reduce the number of necrotic cells. None of tested compounds induced significant genotoxicity, but all of them offered a quite measurable protection against DNA damage. WSDP was found to be the most effective in diminishing the levels of primary and more complex cytogenetic DNA damage in white blood cells. Considering its complex composition, to undoubtedly explain the underlying mechanisms of cyto/radioprotective effects, further studies are needed. Copyright

Quercetin vs chrysin: effect on liver histopathology in diabetic mice.

Effects of flavonoids quercetin and chrysin on lipid peroxidation and histopathological changes in liver of diabetic mice were studied and compared with the antioxidant and reducing ability of quercetin and chrysin and their ability to chelate Fe2+ ions in vitro. Diabetes was induced in Swiss albino mice with a single intravenous injection of alloxan (75 mg kg−1). Two days after alloxan injection, flavonoid preparations (50 mg kg−1 per day) were given intraperitoneally for 7 days in diabetic mice. The lipid peroxidation was evaluated by measuring the malondialdehyde production using the 2-thiobarbituric acid test. Administration of quercetin and chrysin to diabetic mice resulted in a significant decrease in lipid peroxidation level in liver tissue. Treatment of diabetic mice with flavonoids solutions results in decreased number of vacuolated cells and degree of vacuolization of the liver tissue. The protective role of flavonoids against the reactive oxygen species–induced damages in diabetic mice gives a hope that they may exert similar protective action in humans.

The in vivo genotoxicity of cisplatin, isoflurane and halothane evaluated by alkaline comet assay in Swiss albino mice

The aim of this study was to evaluate the genotoxicity of repeated exposure to isoflurane or halothane and compare it with the genotoxicity of repeated exposure to cisplatin. We also determined the genotoxicity of combined treatment with inhalation anaesthetics and cisplatin on peripheral blood leucocytes (PBL), brain, liver and kidney cells of mice. The mice were divided into six groups as follows: control, cisplatin, isoflurane, cisplatin–isoflurane, halothane and cisplatin–halothane, and were exposed respectively for three consecutive days. The mice were treated with cisplatin or exposed to inhalation anaesthetic; the combined groups were exposed to inhalation anaesthetic after treatment with cisplatin. The alkaline comet assay was performed. All drugs had a strong genotoxicity (P < 0.05 vs. control group) in all of the observed cells. Isoflurane caused stronger DNA damage on the PBL and kidney cells, in contrast to halothane, which had stronger genotoxicity on brain and liver cells. The combination of cisplatin and isoflurane induced lower genotoxicity on PBL than isoflurane alone (P < 0.05). Halothane had the strongest effect on brain cells, but in the combined treatment with cisplatin, the effect decreased to the level of cisplatin alone. Halothane also induced the strongest DNA damage of the liver cells, while the combination with cisplatin increased its genotoxicity even more. The genotoxicity of cisplatin and isoflurane on kidney cells were nearly at the same level, but halothane caused a significantly lower effect. The combinations of inhalation anaesthetics with cisplatin had stronger effects on kidney cells than inhalation anaesthetics alone. The observed drugs and their combinations induced strong genotoxicity on all of the mentioned cells.

Synergistic Effects of Irinotecan and Flavonoids on Ehrlich Ascites Tumour-Bearing Mice

Swiss albino mice were given Ehrlich ascites tumour cells (1 × 10(6)) intraperitoneally. For survival analysis and tumour growth analysis, the mice were administered quercetin and naringin (100 mg/kg) daily for 3 consecutive days, beginning on the third day after intraperitoneal (i.p.) injection of Ehrlich ascites tumour cells (1 × 10(6)). Irinotecan was administered ip at a dose of 50 mg/kg on days 1, 13 and 19. For the analysis of cell types and differential count of cells present in the peritoneal cavity, peripheral whole-blood leucocyte count and the comet assay, the mice were treated therapeutically with quercetin and naringin (100 mg/kg) and irinotecan (50 mg/kg) daily for 3 consecutive days beginning on third day after i.p. injection of Ehrlich ascites tumour cells (1 × 10(6)). We observed the synergistic anti-tumour effect expressed as the median survival time of mice treated with naringin in combination with irinotecan. All test components inhibited tumour growth and increased lifespan of mice except quercetin. The total number of cells present in the peritoneal cavity of mice significantly decreased in all treatments except quercetin. Single irinotecan and irinotecan combined with naringin had the highest DNA-damaging potential on peripheral blood leucocytes and lowest primary DNA damage, both in the kidney and liver cells as measured by the alkaline comet assay. Our results showed enhanced anti-tumour activity of irinotecan in combined treatment with flavonoids to reduce the deteriorating reaction of cytostatic drugs.

Effect of competition on habitat utilization in two temperate climate gecko species

Competition over spatial niche utilisation is one of most common competitive interactions between species in sympatry. Moreover, competitive interactions may involve age classes, and can fluctuate temporally. Consequently, evasive strategies that enable co-existence are likely to be important in the evolution of species assemblages. Here we investigate a system of two co-existing species of temperate geckos with similar ecologies (the house gecko, Hemidactylus turcicus and the wall gecko, Tarentola mauritanica), providing an opportunity to study the effect of species interactions. Juveniles and adults of both species were investigated throughout their daily and annual cycle to explore the effect of inter- and intra-specific interactions on microhabitat use. The two species showed differences in habitat use for both age classes in sympatry. In sympatry, T. mauritanica uses more open habitats and is more active. In contrast, H. turcicus is found in more closed habitats, closer to the ground and to vegetation cover. In allopatry, H. turcicus was observed in more open habitats, closer to the ground, and to vegetation cover, when compared to the population in sympatry with T. mauritanica. These differences in habitat usage were significant for both age classes. Moreover, there were differences, both in sympatry and in allopatry, between age classes that were dependent on season. In conclusion, the presence of a competitor induces a spatial shift in individuals of both age classes of H. turcicus. Observed plasticity in habitat utilisation in both age classes of H. turcicus is used to argue for the invasive potential of this species.

DNA damage and repair after exposure to sevoflurane in vivo, evaluated in Swiss albino mice by the alkaline comet assay and micronucleus test

The relationship between DNA damage and repair of peripheral blood leukocytes, liver, kidney and brain cells was investigated in Swiss albino mice (Mus musculus L.) after exposure to sevoflurane (2.4 vol% for 2 h daily, for 3 days). Genetic damage of mouse cells was investigated by the comet assay and micronucleus test. To perform the comet assay, mice were divided into a control group and 4 groups of exposed mice sacrificed on day 3 of the experiment, at 0, 2, 6 or 24 h after the last exposure to sevoflurane. Mean tail length (TL), tail moment (TM), and tail intensity (TI) values were significantly higher in exposed mice (all examined organs) than in the control group. Significant DNA damage immediately after exposure to sevoflurane was observed in leukocytes. Damage induction in the liver, kidney, and brain occurred 6 h later than in leukocytes, as expected according to the toxicokinetics of the drug, where blood is the first compartment to absorb sevoflurane. However, none of the tested tissues revealed signs of repair until 24 h after the exposure. To distinguish the unrepaired genome damage in vivo, the micronucleus test was applied. Number of micronuclei in reticulocytes showed a statistically significant increase, as compared with the control group at all observed times after the treatment.

Genotoxicity and Cytotoxicity of Cisplatin Treatment Combined with Anaesthetics on EAT Cells In Vivo

In this study, DNA damage in tumour cells, as well as irreversible cell damage leading to apoptosis induced in vivo by the combined application of cisplatin and inhalation anaesthetics, was investigated. The genotoxicity of anaesthetics on Ehrlich ascites tumour (EAT) cells of mice, alone or in combined application with cisplatin, was estimated by using the alkaline comet assay. The percentage of EAT cell apoptosis was quantified by flow cytometry. Groups of EAT-bearing mice were (i) treated intraperitoneally with cisplatin, (ii) exposed to repeated anaesthesia with inhalation anaesthetic, and (iii) subjected to combined treatment of exposure to anaesthetics after cisplatin for 3 days. Sevoflurane, halothane and isoflurane caused strong genotoxic effects on tumour cells in vivo. The tested anaesthetics alone showed no direct effect on programmed cell death although sevoflurane and especially halothane decreased the number of living EAT cells in peritoneal cavity lavage. Repeated anaesthesia with isoflurane had stimulatory effects on EAT cell proliferation and inhibited tumour cell apoptosis (6.11%), compared to the control group (10.26%). Cisplatin caused massive apoptosis of EAT cells (41.14%) and decreased the number of living EAT cells in the peritoneal cavity. Combined cisplatin and isoflurane treatment additionally increased EAT cell apoptosis to 51.32%. Combined treatment of mice with cisplatin and all anaesthetics increased the number of living tumour cells in the peritoneal cavity compared to cisplatin treatment of mice alone. These results suggest that the inhalation of anaesthetics may protect tumour cells from the cisplatin-induced genotoxic and cytotoxic effects.

Evaluation of DNA damage in vivo induced by combined application of cisplatin and sevoflurane

Background and objective The influence of the combined application of cisplatin and sevoflurane on a variety of cell types of healthy mice or mice bearing Ehrlich ascites tumour has been investigated in an in vivo study. Methods The alkaline comet assay method was carried out on peripheral blood leucocytes, brain, liver, kidney and tumour cells of healthy mice or mice bearing Ehrlich ascites tumour. Groups of mice were treated intraperitoneally with cisplatin, exposed to sevoflurane or by combined treatment of sevoflurane after treatment with cisplatin for 3 consecutive days. Results The in vivo exposure to sevoflurane induced genotoxicity to all assayed cells. A strong synergistic genotoxic effect to peripheral blood leucocytes, liver and kidney cells was found in mice receiving both cisplatin and sevoflurane. In contrast, a decrease of the comet tail lengths of brain cells in the combined treatments was found as compared to cisplatin alone in both healthy (P < 0.001) and Ehrlich ascites tumour‐bearing mice (P < 0.05), respectively. In addition, Ehrlich ascites tumour cells of mice treated with combined treatments showed a decrease in tail lengths (P < 0.001). These findings indicate an antagonistic effect of combined treatments. Conclusion Treatment of mice with cisplatin and sevoflurane induced genotoxic effect in peripheral blood leucocytes, liver, kidney, brain and Ehrlich ascites tumour cells; synergistic effect of combined treatments was expressed in all cells but brain and Ehrlich ascites tumour cells.