RESUMEN
The redox cycling of anthracyclines promotes the formation of free radicals which are believed to play a central role in their cardiotoxicity. A number of observations indicate that the mechanism of the antineoplastic effect of anthracyclines is independent of their cardiotoxic effect and that it may be possible to prevent toxicity without interfering with therapeutic effect. Iron plays an important role in anthracycline toxicity by promoting the conversion of superoxide into highly toxic hydroxyl radicals through the Haber-Weiss reaction. Conversely, iron deprivation by its high-affinity binding to iron chelating compounds may inhibit anthracycline toxicity by interfering with free radical formation. ICRF-187, a bispiperazonedione which is hydrolyzed intracellularly into a bidentate chelator resembling EDTA, is able to decrease adriamycin-induced free hydroxyl radical formation and to prevent the development of clinical cardiac toxicity in patients receiving long-term anthracycline therapy. Our studies in rat heart cell cultures have shown that iron overload aggravates anthracycline toxicity and that this interaction can be prevented by prior iron chelating treatment. Since iron overload caused by multiple blood transfusions and bone marrow failure is a common condition in patients requiring anthracycline therapy, these observations may have significant clinical implications to the prevention of anthracycline cardiotoxicity.
Asunto(s)
Antibióticos Antineoplásicos/toxicidad , Cardiopatías/inducido químicamente , Quelantes del Hierro/farmacología , Hierro/toxicidad , Animales , Antibióticos Antineoplásicos/efectos adversos , Radicales Libres , HumanosRESUMEN
The interrelation between iron, iron chelation, and anthracycline toxicity was investigated in a heart cell culture system. Two indicators of cellular damage have been used, lactate dehydrogenase (LDH) release and cell contractility. Both of these indicators have shown a marked increase in doxorubicin toxicity by prior iron loading. This was not a simple additive effect, because at the concentrations used, iron had only a minimal effect on LDH release and no effect at all on contractility, whereas doxorubicin had only a minor effect on contractility. Deferoxamine (DF) treatment of iron-loaded heart cells resulted in a marked decrease in anthracycline toxicity as judged both by LDH leakage and cell contractility. However, DF treatment of normal heart cells had no measurable protective effect against doxorubicin toxicity, whether DF was administered before or simultaneously with doxorubicin. Doxorubicin treatment did not alter cellular malondialdehyde (MDA) concentrations in either normal or iron-loaded cells. Conversely, the protective effect of DF in iron-loaded cells and its failure to prevent anthracycline toxicity in normal cells were both associated with a significant decrease in MDA measurements. Our data indicate that iron overload aggravates anthracycline toxicity and that this interaction may be prevented by effective iron chelating therapy. Because patients requiring anthracycline therapy often have increased tissue iron stores caused by multiple blood transfusions and bone marrow suppression, our observations may have important implications for the prevention of anthracycline toxicity.