The effect of the nitroxide pirolin on oxidative stress induced by doxorubicin and taxanes in the rat brain.

The anticancer drugs doxorubicin (DOX), paclitaxel (PTX) and docetaxel (DTX) have been proven to induce oxidative stress (OS)-dependent side-effects in non-targeted tissues. In normal conditions, the blood-brain barrier (BBB) prevents these drugs from penetrating into the brain. However, some studies have demonstrated that small amounts of DOX can penetrate the brain via an oxidatively impaired BBB and cause damage, which suggests that including antioxidants in chemotherapy could possibly protect the brain against the toxicity of anticancer drugs. We investigated whether DOX, DTX and PTX can induce oxidative damage in rat brains in vivo and whether inclusion of the nitroxyl antioxidant Pirolin (PL) to DOX/taxane chemotherapy can protect the brain from the OS toxicity of these drugs. Wistar rats received i.p. a single dose (10 mg/kg b.w.) of DOX, DTX, PTX or PL alone or a combination of a drug + PL. After four days, the rats were anesthetized, the brains were excised, homogenized and used for the measurements of lipid peroxidation (LPO), thiol groups, activities of antioxidant enzymes, DNA damage and tumor necrosis factor-α (TNF-α), neuronal nitric oxide synthase (nNOS) and poly (ADP-ribose) polymerase-1 (PARP-1) expression. The results were analyzed using the Kruskal-Wallis and Conover-Inman tests or ANOVA and the Tukey-Kramer test. Doxorubicin, PTX and DTX induced OS, DNA damage and changes in expression of TNF-α, nNOS and PARP-1 in the rat brain. Pirolin alone increased LPO, manganese superoxide dismutase (MnSOD) and catalase (CAT) activities and the expression of PARP-1 but decreased TNF-α expression. PL, in combination with anticancer drugs, partially protected the rat brain against the toxic effects of DOX and taxanes. The best protective effects of PL were obtained with PTX. Pirolin partially attenuated brain damage caused by DOX/taxanes, highlighting its potential application in protecting the brain against DOX-, DTX- and PTX-evoked OS.

Antioxidant action of six Trifolium species in blood platelet experimental system in vitro.

This study includes a comparative evaluation of antioxidant effects of plant extracts (1.5-50.0 µg/ml), derived from six clover (Trifolium) species: T. alexandrinum L., T. fragiferum L., T. hybridum L., T. incarnatum L., T. resupinatum var. majus Boiss., and T. resupinatum var. resupinatum L. Chemical profiles of the extracts contained three or four groups of (poly)phenolic compounds such as phenolic acids, clovamides, isoflavones, and other flavonoids. Antioxidant properties of Trifolium extracts were assessed as the efficacy to reduce oxidative and nitrative damage to blood platelets, exposed to 100 µM peroxynitrite-induced oxidative stress in vitro. Antioxidant actions of the examined extracts were determined by the following biomarkers of oxidative stress: thiol groups, 3-nitrotyrosine, lipid hydroperoxides, and thiobarbituric acid-reactive substances (TBARS). Despite the significant differences in the chemical composition (the total phenolic concentrations varied between 11.30 and 52.55 mg/g of dry mass) of Trifolium extracts, we observed noticeable protective effects of almost all tested plant preparations. The T. alexandrinum extract, containing the highest concentration of phenols, was the most effective antioxidant among the tested extracts. On the other hand, the T. incarnatum extract, which contained a comparable total phenolic content (49.77 mg/g), was less efficient in prevention of tyrosine nitration and generation of TBARS. These findings indicate on the important role of individual phenolic components of the examined clover extracts for the final antioxidative effects. Antioxidative properties of the remaining extracts were noticeably weaker.

Oxidative stress induced in rat liver by anticancer drugs doxorubicin, paclitaxel and docetaxel.

PURPOSE: Oxidative stress generated by anticancer drugs in non-targeted tissues, is considered as a significant factor responsible for their severe side effects, e.g. cardiotoxicity, neurotoxicity and hepatotoxicity. Lack of data on the effect of concurrent administration of commonly used anticancer drugs: doxorubicin (DOX), paclitaxel (PTX) and docetaxel (DTX) on normal tissue, prompted us to examine the markers of oxidative stress in the liver of rats treated with these drugs. MATERIAL/METHODS: Male Wistar rats of average weight 200 g were injected intraperitoneally (i.p.) with 10 mg/kg of body weight (b.w.) of DOX, PTX and DTX. The drugs were given alone or in combinations DOX+taxane. The activities of superoxide dismutase (SOD), catalase (CAT), low molecular weight and total thiols and thiobarbituric acid-reactive substances (TBARS) were estimated. RESULTS: Combination of two drugs generated greater changes than single agents. Concurrent administration of DOX and PTX increased SOD activity and TBARS, decreased the amount of low molecular weight and total thiols, but did not cause any changes in the activity of catalase. Combination of DOX and DTX induced similar changes except for the activity of catalase, which decreased after the treatment. Of the three drugs only DTX significantly decreased the activity of SOD. However, both taxanes increased the activity of catalase. Although a decrease in concentration of -SH groups, depletion of glutathione and an increase of TBARS were observed after treatment with single drugs, the changes were not statistically significant. CONCLUSION: Concurrent administration of DOX and taxane induced enhanced oxidative stress in comparison to single drugs, which suggests their synergistic prooxidant mode of action in liver.

Nitroxide pirolin reduces oxidative stress generated by doxorubicin and docetaxel in blood plasma of rats bearing mammary tumor.

Combination of doxorubicin (DOX) and docetaxel (DTX) is clinically effective against many drug-refractory cancers, nevertheless, enhanced side effects, e.g. cardiotoxicity related to oxidative damage of tissue macromolecules is observed. Nitroxides represent an attractive class of synthetic compounds to ameliorate DOX-DTX toxicity in non-targeted tissues due to their antioxidant and iron-oxidizing properties. The aim of the study was to define the ability of 3-carbamoylpyrroline nitroxyl derivative pirolin (PL) to mitigate oxidative damage to blood plasma proteins and lipids induced by DOX-DTX chemotherapy in Sprague-Dawley rats bearing DMBA-induced mammary tumor. Additionally we also evaluated: i) pro-oxidant and antioxidant activity of pirolin administered as a single agent according to different regimens and ii) differences in biomarkers of the oxidative stress between healthy rats and rats with DMBA-induced mammary tumors. The extent of oxidative stress was evaluated on the basis of its foremost biomarkers: thiol and carbonyl groups, lipid peroxidation products (hydroperoxides, TBARS), activity of antioxidant defense enzyme superoxide dismutase (SOD) and non-enzymatic antioxidant capacity (NEAC). We have found that pirolin alone displayed dual, antioxidant and pro-oxidant activity depending on the regimen of treatment. Daily treatment for 2 weeks increased the amount of thiols, and decreased the protein carbonyl groups. Three administrations of pirolin at 3-week intervals did not influence thiol content but increased hydroperoxides, TBARS and carbonyl groups. Chemotherapy employing DOX-DTX combination caused considerable oxidative stress in the plasma. Significant and dose-dependent oxidative damage to lipids and proteins with concomitant thiol depletion were evident in treated animals. Drugs also increased SOD activity and NEAC. Association of pirolin with DOX-DTX chemotherapy resulted in a partial amelioration of oxidative stress generated by anticancer drugs. This study indicates that a nitroxyl compound pirolin applied as a single agent in vivo can display both antioxidant and pro-oxidant properties but in conjunction with DOX-DTX it is able to protect partially blood plasma against oxidative stress generated by chemotherapy. The outcome, however, seems to be highly dependent on the ratio between the doses of employed anticancer drugs and the nitroxide.

Different effectiveness of piperidine nitroxides against oxidative stress induced by doxorubicin and hydrogen peroxide.

The piperidine nitroxides Tempamine and Tempace have been studied for their effect on doxorubicin (DOX) and hydrogen peroxide (H(2)O(2)) cytotoxicity in immortalized B14 cells, a model for neoplastic phenotype. The significance for nitroxide performance of the substituent in position 4 of the piperidine ring was evaluated. The cells were exposed to DOX/H(2)O(2) alone or in combination with the nitroxides Tempamine or Tempace. Two other piperidine nitroxides, Tempo and Tempol, were used for comparison. All the nitroxides except Tempamine modestly reduced DOX cytotoxicity. Tempamine evoked a biphasic response: at concentrations lower than 200 micromol/L the nitroxide decreased DOX cytotoxicity, while at concentrations higher than 200 micromol/L, it enhanced DOX cytotoxicity. In contrast to Tempo and Tempol, Tempamine and Tempace ameliorated hydrogen peroxide cytotoxicity, but none of the nitroxides influenced TBARS stimulated by hydrogen peroxide. The cytoprotective effect of Tempace, Tempo and Tempol in DOX-treated cells correlated with the inhibition of DOX-induced lipid peroxidation. The bioreduction rates of the investigated nitroxides differed significantly and were variously affected by DOX depending on the nitroxide substituent. In combination with DOX, Tempo and Tempol were reduced significantly more slowly, while no influence of DOX on Tempamine and Tempace bioreduction was observed. Our results suggest that the structure of the 4-position substituent is an important factor for biological activity of piperidine nitroxides. Among the investigated nitroxides, Tempace displayed the best protective properties in vitro but Tempamine was the only nitroxide that potentiated cytotoxicity of DOX and did not influence DOX-induced lipid peroxidation. However, this nitroxide showed different performance depending on its concentration and conditions of oxidative stress.