Preventive role of carvedilol in adriamycin-induced cardiomyopathy

Due to the aging of the populations of developed countries and a common occurrence of risk factors, it is increasingly probable that a patient may have both cancer and cardiovascular disease. In addition, cytotoxic agents and targeted therapies used to treat cancer, including classic chemotherapeutic agents, monoclonal antibodies that target tyrosine kinase receptors, small molecule tyrosine kinase inhibitors, and even antiangiogenic drugs and chemoprevention agents such as cyclooxygenase-2 inhibitors, all affect the cardiovascular system. One of the reasons is that many agents reach targets in the microenvironment and do not affect only the tumor. Combination therapy often amplifies cardiotoxicity, and radiotherapy can also cause heart problems, particularly when combined with chemotherapy. In the past, cardiotoxic risk was less evident, but it is increasingly an issue, particularly with combination therapy and adjuvant therapy. Today's oncologists must be fully aware of cardiovascular risks to avoid or prevent adverse cardiovascular effects, and cardiologists must now be ready to assist oncologists by performing evaluations relevant to the choice of therapy. There is a need for cooperation between these two areas and for the development of a novel discipline, which could be termed cardio-oncology or onco-cardiology. Here, we summarize the potential cardiovascular toxicities for a range of cancer chemotherapeutic and chemopreventive agents and emphasize the importance of evaluating cardiovascular risk when patients enter into trials and the need to develop guidelines that include collateral effects on the cardiovascular system. We also discuss mechanistic pathways and describe several potential protective agents that could be administered to patients with occult or overt risk for cardiovascular complications.

The aim of this study was to determine the protective effect of carvedilol in anthracycline (ANT)-induced cardiomyopathy (CMP). Despite its broad effectiveness, ANT therapy is associated with ANT-induced CMP. Recent animal studies and experimental observations showed that carvedilol prevented development of CMP due to chemotherapeutics. However, there is no placebo-controlled clinical trial concerning prophylactic carvedilol use in preventing ANT-induced CMP. Patients in whom ANT therapy was planned were randomized to administration of carvedilol or placebo. We enrolled 25 patients in carvedilol and control groups. In the carvedilol group, 12.5 mg once-daily oral carvedilol was given during 6 months. The patients were evaluated with echocardiography before and after chemotherapy. Left ventricular ejection fraction (EF) and systolic and diastolic diameters were calculated. At the end of 6 months of follow-up, 1 patient in the carvedilol group and 4 in the control group had died. Control EF was below 50% in 1 patient in the carvedilol group and in 5 in the control group. The mean EF of the carvedilol group was similar at baseline and control echocardiography (70.5 vs. 69.7, respectively; p = 0.3), but in the control group the mean EF at control echocardiography was significantly lower (68.9 vs. 52.3; p < 0.001). Both systolic and diastolic diameters were significantly increased compared with basal measures in the control group. In Doppler study, whereas E velocities in the carvedilol group decreased, E velocities and E/A ratios were significantly reduced in the control group. Prophylactic use of carvedilol in patients receiving ANT may protect both systolic and diastolic functions of the left ventricle.

The anthracyclines are the class of antitumor drugs with the widest spectrum of activity in human cancers, and only a few cancers (eg, colon cancer) are unresponsive to them. The first two anthracyclines were developed in the 1960s. Doxorubicin (DOX) differs from daunorubicin (DNR) only by a single hydroxyl group. This fact has spurred researchers worldwide to find analogs of DOX that have less acute toxicity, cause less cardiomyopathy, can be administered orally, and/or have different, or greater, antitumor efficacy. Five DOX/DNR analogs are marketed in other countries, and one (idarubicin) is available in the United States. None of these analogs have stronger antitumor efficacy than the original two anthracyclines, but there are some differences in toxicity. Methods have been fashioned to keep the peak plasma level of DOX muted to minimize cardiotoxicity, but the only apparently effective method available so far (prolonged drug infusion) is cumbersome. The bisoxopiperazine class of drugs (especially dexrazoxane) provides protection against anthracycline-induced cardiomyopathy and has much promise for helping mitigate this major obstacle to prolonged use of the anthracyclines. The DOX analogs being evaluated in the 1990s have been selected for their ability to overcome multidrug resistance in cancer cells. Thirty years after discovery of the anticancer activity of the first anthracycline, some means of reducing anthracycline toxicity have been devised. Current studies are evaluating increased doses of epirubicin to improve anthracycline cytotoxicity, while limiting cardiotoxicity, but at present DOX still reigns in this drug class as the one having the most proven cancerocidal effect.