Luisa Paracchini

Protective activity of the spin trap tert-bytyl-α-phenyl nitrone (PBN) in reperfused rat heart

Abstract The aim of this work was to ascettain whether free radicals play a causal role in the injury occurring in myocardial ischemia and reperfusion. To this purpose we observed whether spin-trapping compounds protect the heart when used at a concentration capable of reacting with free radicals. The lipophilic spin trap α-phenyl-t-butyl nitrone (PBN) was used because it is taken up by the myocites. Isolated Langendorff rat hearts were subjected to ischemia according to two schemes: “Model A” = 30 min zero-flow ischemia followed by 30 min reperfusion; “Model B” = 60 min of low-flow ischemia (10% of the individual value; N 2 saturated) followed by 30 min reperfusion. Treated groups received in addition 5.0 m m PBN which was supplied continuously. The following parameters were measured throughout the experiment: contractile performance (RPP); coronary flow (CF); CPK; phosphocreatine (PCr), ATP, inorganic phosphate ( P i ), intracellular pH (pH i ). The pathology obtained by “Model A” is more severe than that of Model B, and partly irreversible. During the ischemic phase in “Model A”, contractility, PCr and ATP dropped to near zero; during initial reflow CPK rose about 13-fold and P i rose 2.5-fold, while pH i decreased to 6.1. During reperfusion, a partial recovery of PCr, P i and pH i was observed, while RPP and ATP did not increase; PBN treatment improved significantly PCr and CPK, while the other parameters were unaffected. During ischemia, “Model B” hearts showed a drop of contractility to near zero, of PCr to 35%, of ATP to 50%; CPK rose 7-fold and P i 1.5-fold; pH i was not modified. During reperfusion, all parameters recovered in part, with exception of P i . PBN developed a marked protective activity on all tested parameters, which gained a nearly normal value. The results of the present investigations show that the lipophilic spin trap PBN partly protects the heart from the ischemia/reperfusion injury, thus confirming that free radicals play a causal role in this pathology; the continuous loading of the tissue with the drug can be an important factor for obtaining the protective effect.

Protective effects of spin-trapping agents on adriamycin-induced cardiotoxicity in isolated rat atria

Adriamycin (ADR) is known to exert a severe negative inotropic effect on isolated myocardial preparations; a role for free radical generation has been hypothesized. Spin-trapping of free radicals has been extensively exploited in ESR studies, both in cell-free systems and in intact tissues. The interaction between spin-traps and free radicals should in principle stop the reaction cascade leading to cellular damage. Based on this hypothesis, the possible cardioprotective action of three spin-trapping agents, 5,5-dimethyl-l-pyrroline-N-oxide (DMPO), N-tert-butyl-alpha-phenylnitrone (PBN) and alpha-(4-pyridyl 1-oxide) N-tert-butylnitrone (POBN), was tested on isolated rat atria incubated in the presence of ADR; maximal non-cardiotoxic concentrations were used (50, 10 and 50 mM respectively) in order to achieve a maximal spin-trapping effect. A varying degree of protection was observed with the three compounds, directly correlated to their hydrophobicity, as assessed by chloroform/water partition coefficients. It is proposed that ADR-induced free radical generation is responsible for the acute cardiotoxic effects of the drug; this seems to be a site-specific mechanism restricted to one or more hydrophobic cellular compartment/s, since only lipophilic spin-trapping agents are able to prevent the development of the negative inotropic effect of ADR.

Protective effect of dietary selenium supplementation on delayed cardiotoxicity of adriamycin in rat: Is PHGPX but not GPX involved?

The involvement of Se enzymes in the protection against the oxidative stress induced by adriamycin (ADR) in rat heart has been studied in animals fed for 10 weeks at three different levels of Se content (low = 0.02 ppm; normal = 0.5 ppm; high = 1.0 ppm) and receiving a weekly injection of 3 mg/kg ADR for 4 weeks. ECG (QaT duration) and contractility of isolated atria were measured. The high-Se diet showed a significant protection on both parameters. To assess the hypothesis that an increase of specific activity of antioxidant Se enzymes may account for the cardioprotective effect of selenium, glutathione peroxidase (GPX), and phospholipid hydroperoxide glutathione peroxidase (PHGPX) were tested. The assays were performed on ventricles isolated from treated rats. At the end of the experimental period, GPX (cytosolic enzyme) did not show any significant difference between controls and ADR-treated at any level of Se content, thus excluding its involvement in the cardioprotection observed in high-Se ADR-treated animals. PHGPX, which is present both in cytosol and in the cell membrane, showed a trend to increase its activity in the presence of ADR treatment only in the membrane fraction; however, the statistical significance was reached only in the low-Se group (+100%). This observation suggests that membrane PHGPX might be involved in the cellular mechanism of adaptation of the heart to the toxic effects of ADR; however, the behavior of these enzymes does not seem to account for the significant protection of selenium supplementation both on ECG and on contractile indices of ADR cardiotoxicity.(ABSTRACT TRUNCATED AT 250 WORDS)

Reduction of myofibrillar ATPase activity and isomyosin shift in delayed doxorubicin cardiotoxicity

The aim of this study was to determine whether variations of isomyosin expression occurred during doxorubicin-induced cardiomyopathy. A suitable experimental model in which pure delayed cardiotoxic effects could be easily studied was adopted. Young adult female Sprague Dawley rats received 9 mg/kg of doxorubicin (DXR) i.v. divided into three subdoses of 3 mg/kg every third day. Control animals received equal volumes of saline. The animals were examined 9 weeks after treatment. At this time the animals treated with DXR showed ECG alterations, reduction of body weight and a marked decrease of both atrial and ventricular mass, but were still fully hemodynamically compensated. Loss of myofibrillar material could be documented by the reduced recovery of myofibril and myosin. The contractile response of papillary muscles isolated from the right ventricle of treated animals was markedly impaired. Ca-Mg-activated and Mg-activated myofibrillar ATPase activity and Ca-activated myosin ATPase activity were determined on ventricular myocardium of control and treated animals. Both myofibrillar and myosin ATPase activities were found to be significantly reduced. Pyrophosphate gel electrophoresis of purified myosin was carried out. The isomyosin pattern of DXR-treated animals showed a pronounced shift towards V3, the percent of alpha heavy chains being 54.6% in treated rats (80.5% in control rats). This isomyosin shift can explain the reduced myofibrillar and myosin ATPase activity found in treated animals.

Glycogen turnover and anaplerosis in preconditioned rat hearts

Using (13)C NMR, we tested the hypothesis that protection by preconditioning is associated with reduced glycogenolysis during ischemia. Preconditioned rat hearts showed improved postischemic function and reduced ischemic damage relative to ischemic controls after 30 min stop-flow ischemia and 30 min reperfusion (contractility: 30+/-10 vs. 2+/-2%; creatine kinase release: 41+/-4 vs. 83+/-15 U/g; both P<0.05). Preconditioning decreased preischemic [(13)C]glycogen by 24% (a 10% decrease in total glycogen), and delayed ischemic [(13)C]glycogen consumption by 5-10 min, reducing ischemic glycogenolysis without changing acidosis relative to controls. Upon reperfusion, glycogen synthesis resumed only after preconditioning. Glutamate (13)C-isotopomer analysis showed recovery of Krebs cycle activity with higher anaplerosis than before ischemia (23+/-4 vs. 11+/-3%, P<0.05), but in controls reperfusion failed to restore flux. Compared to control, preconditioning before 20 min ischemia increased contractility (86+/-10 vs. 29+/-14%, P<0.05) and restored preischemic anaplerosis (13+/-3 vs. 39+/-9%, P<0.05). Preconditioning is associated with reduced glycogenolysis early during ischemia. However, protection does not rely on major variations in intracellular pH, as proposed earlier. Our isotopomer data suggest that preconditioning accelerates metabolic and functional recovery during reperfusion by more efficient/active replenishment of the depleted Krebs cycle.

Cardiotoxicity and antitumor activity of a copper(II)-doxorubicin chelate

SummaryThe cardiotoxic and cytotoxic effects of the Cu(II)-doxorubicin (DXR) complex [Cu(DXR)]n are compared with those of the parent drug. It is shown that 10−4M [Cu(DXR)]n has no depressant effects on isolated rat atria, in contrast with an equimolar concentration of the parent drug. No differences were found between the cytotoxic activities of the Cu(II) complex and free DXR on B16 melanoma and HeLa cells. A reduced penetration of the polymeric [Cu(DXR)]n into the myocardial cells as compared with the free drug was invoked to account for the absence of cardiotoxicity of the DXR complex. On the other hand, the observation that copper-complexation does not affect the cytotoxicity of the drug suggests that extracellular as well as intracellular mechanisms may be involved in the development of its antitumor activity.

Cardiotoxicity induced by doxorubicin in vivo: Protective activity of the spin trap alpha-phenyl-tert-butyl nitrone

The role of free radical generation in the development of the acute cardiotoxicity induced by doxorubicin (DXR) in the rat and the protective activity of anti-radical drugs were investigated in in vivo experiments by evaluating the body weight curve, ECG, contractile performance and coronary flow up to 10 days after DXR. A lipophilic spin trap (alpha-phenyl-tert-butyl nitrone, PBN) was continuously administered at a dose of 0.65 mg/kg every hour for 2 weeks by an intraperitoneal osmotic pump. DXR was administered i.v. at a dose of 9 mg/kg 3 days after beginning the PBN infusion. DXR impaired ECG and body weight gain after 3 days (partly reversible at later times), while contractility and coronary flow were significantly impaired throughout the experimental time. PBN was shown to prevent the DXR-induced alterations of contractility and coronary flow, while ECG was non-significantly improved. The body weight curve was not affected. Since the dose of PBN used does not produce pharmacological effects, the protective activity in rats receiving DXR indicates that free radicals may play a causal role in the acute cardiotoxicity in vivo. The use of suitable spin traps and administration schedules seems to be an interesting approach for the prevention of radical-dependent pathologies.

The hydrophilic spin trap, 5,5-dimethyl-1-pyrroline-1-oxide, does not protect the rat heart from reperfusion injury.

The role and site of free radical generation in myocardial ischemia/reperfusion injury were investigated using the hydrophilic spin trapping agent, 5,5-dimethyl-1-pyrroline-1-oxide (DMPO). DMPO (40 mM) proved ineffective in preserving the contractile performance and energy metabolism of Langendorff-perfused rat hearts following ischemia and reperfusion. This result, which is in contrast with the cardioprotection observed with hydrophobic spin traps, suggests that free radicals are generated intracellularly under these conditions.

Are Oxygen Radicals Responsible for the Acute Cardiotoxicity of Doxorubicin

Oxygen-derived free radicals nave been implicated as mediators of the acute cardiotoxic effects induced by doxorubicin (DXR) treatment, Superoxide anions (O 2 - ) may be generated by xanthine oxidase or by one-electron reduction of DXR to the corresponding semiquinone and subsequent electron transfer to molecular oxygen. (O 2 - ) generation plays a central role in the sequence of reactions leading to the formation of the more active hydroxyl radical (·OH) according to the Haber-Weiss reaction (figure 1) (1). An additional source of active oxygen species is represented in vivo by the leu Kocytic enzyme myeloperoxidase, since DXR has been shown to stimulate the production of oxidants by neutrophils (2). Free radical-mediated membrane lipo peroxidation and the subsequent impairment of ion transport processes would eventually account for DXR-induced cardiodepressant effects (3–5).

Effect of calcium inhibitors and calcium mobilizers on doxorubicin accumulation in rat myocardial tissue.

The effect of four calcium-modulating agents on myocardial doxorubicin (DXR) accumulation was studied: the calcium-inhibitors verapamil (0.1 microM), trifluoperazine (5 microM) and flunarizine (0.05 microM) and the calcium-mobilizer taurine (50 mM). Myocardial cells of isolated Langendorff rat hearts receiving the drugs showed a significantly enhanced 14C-DXR uptake. These observations are in contrast with the hypothesis that DXR accumulation processes may be related to a decrease in calcium influx and suggest that a combined therapy with DXR and calcium-modulating agents might enhance the drug-induced cardiotoxicity.