View clinical trials related to Cardiotoxicity.
Filter by:This is a prospective, exploratory, randomised clinical trial. Patients with diagnosed cancer that are to be treated with 5-fluorouracil (5-FU) will be randomised into standard oncological treatment or a cardiological assessment prior to the 5-FU treatment. The investigators hypothesize that aggressive management of ischemic risk factors in asymptomatic patients will reduce the number of hospitalisations and investigations for acute coronary syndrome during and after 5-FU treatment and that patients with high coronary artery calcium scores are more likely to experience chest pain during the treatment with 5-FU.
This phase III trial studies how well carvedilol works in preventing cardiac toxicity in patients with human epidermal growth factor receptor (HER)-2-positive breast cancer that has spread to other places in the body. A beta-blocker, such as carvedilol, is used to treat heart failure and high blood pressure, and it may prevent the heart from side effects of chemotherapy.
Lung cancer is the most common cause of cancer death in Canada. For approximately 30% of patients that present with locally-advanced non-small cell lung cancer (NSCLC), the standard treatment is curative-intent concurrent chemoradiotherapy. Outcomes remain poor, with 5-year survival of only 20%. Despite the long-held belief that higher radiation doses lead to improved overall survival (OS), the landmark randomized trial (RTOG 0617) showed the opposite. The investigators hypothesize that the inferior survival observed may be due to unexpected heart toxicity as secondary analysis revealed that the heart dose was a strong predictor of inferior OS. Up to now, change in heart function is typically detected histologically, requiring autopsy tissue. Therefore, a non-invasive marker of early heart damage is required. Hybrid PET-MRI has become available in Canada only recently. The ability to simultaneously perform metabolic imaging with functional and tissue imaging allows for novel assessment of heart toxicity. The primary objective is to examine the utility of hybrid PET-MRI and DCE-CT to assess acute changes in heart function and to measure inflammation before, and six weeks after NSCLC radiotherapy. A pilot of 20 patients with Stage I-III NSCLC will be enrolled. The findings of this study will aid in the design of new studies to reassess dose escalation for locally advanced NSCLC while limiting the risk of heart toxicity. FDG PET will be used to simultaneously assess both cardiac inflammation and tumour response. Quantitative DCE-CT will also be used to measure ventilation and perfusion changes in the normal lung and tumour after radiotherapy, providing image data that can comprehensively assess both tumour response and potential toxicity in both the heart and lungs. Such information is crucial in understanding the disease and its response to treatment. This data will also aid in the design of radiation techniques that spare the heart in other patients with any thoracic malignancies, including breast cancer, lymphoma, and esophageal cancer.
Chemotherapy or radiation therapy-induced cardiotoxicity are well-recognized side effects in patients with cancer. The clinical significance of cardiotoxicity is growing with increasing cancer survivor-ship. Left ventricular (LV) functional assessment is the standard of reference to diagnose chemotherapy- or radiation therapy-induced cardiotoxicity. The investigators will investigate the usefulness of T1 mapping parameters for early detection and prediction of chemotherapy-, radiation therapy-, or other therapy-induced cardiotoxicity in breast cancer patients This study aimed to achieve early detection of chemotherapy- or radiation therapy-induced cardiotoxicity using T1 mapping magnetic resonance imaging (MRI) and determine a prognostic imaging factor of chemotherapy- or radiation therapy-induced cardiotoxicity in patients treated for breast cancer.
This is a pilot prospective cohort study, in adult female subjects 18-85 years old with a diagnosis of invasive breast cancer who are planned for anthracycline-inclusive chemotherapy and followed up for a time period of 6 months post completion of anthracycline chemotherapy. They will participate in blood and imaging tests with a goal of determining the best method for predicting the occurrence of cardiotoxicity in this subpopulation.
The survival rate of cancer patients has greatly increased over the past decades' mainly due to early detection and the use of new medications with higher doses and combined protocols. This achievement comes with the price of cardio toxicity, leading to cardiac dysfunction ranged from transient asymptomatic left ventricular dysfunction to cardiac death. In the long term, the risk of death from cardiovascular causes exceeds that of tumor recurrence for many types of cancer. As a result of the increasing number of long-term cancer survivors the magnitude of this problem is growing. Early identification of cardio toxicity can be identified by clinical follow-up and the use of electrocardiography, cardiac biomarkers (Troponin, brain natriuretic peptide) and echocardiogram. Past studies imply that the addition of angiotensin-converting-enzyme inhibitor (ACE inhibitor) and beta blockers to the patient's treatment may prevent the development of cardiac dysfunction. However, currently there are no specific or clear guidelines for the follow-up and management of cardio-toxicity in cancer patients. The aim of the study: To try to identify who are the patients at increased risk for developing cardio toxicity, by follow up of clinical evaluation, cardiac biomarkers and echocardiogram examination, in purpose of early diagnosis, management and prevention of cardiac events. For achieving this the investigators will build a registry which will include all the oncologic patients going an evaluation in the cardio-oncology clinic in the Tel Aviv Medical Center .
This research study is evaluating the use of Cardiac Magnetic Resonance Imaging (CMR) as a method of detecting early signs of damage to the heart that can be associated with anthracycline-based chemotherapy for the treatment of breast cancer.
observational prospective study, designed for patients with colorectal cancer receiving for the first time 5-FU or capecitabine, with or without other chemotherapy combinations.
Cancer survival has improved steadily due to earlier detection and treatment. Despite the established efficacy of anthracycline chemotherapy, its damaging effects on the heart (cardiotoxicity) limits treatment and confers acute and long term adverse cardiovascular consequences. Protective strategies for the heart (cardioprotection) with iron binders (chelation), heart rate (beta blockade) and blood pressure (renin angiotensin inhibition) medications have demonstrated promise in adult cancer patients, but these treatments are typically prescribed only after significant changes in heart chamber size and pumping ability are detected by imaging investigations (myocardial dysfunction). Furthermore, these conventional therapies are constrained by important side effects that affect bone marrow, blood pressure, and the kidneys. Remote ischaemic conditioning (RIC) protects the heart by activating cell survival pathways through brief repeated inflations and deflations of a blood pressure cuff to limit blood flow temporarily (noninjurious ischaemia). These innate survival mechanisms prevent part of the cellular injury that occurs during the ischaemia reperfusion cascade during a heart attack (myocardial infarction). Ischaemia reperfusion injury also shares common biochemical pathways with anthracycline cardiotoxicity, and thus RIC may be a novel form of nonpharmacological cardioprotection that can be applied when undergoing anthracycline chemotherapy. The investigators propose a pilot single centre randomised controlled trial to investigate the effect of RIC on reducing heart muscle damage (myocardial injury) in anthracycline-treated cancer patients. The investigators will assess subclinical myocardial injury using high-sensitivity blood tests (troponin T levels) and advanced imaging techniques, monitor heart rhythm disturbances (cardiac arrhythmia) and analyse metabolic changes in urine and blood during chemotherapy, at specified time points, and follow up to 5 years after completing chemotherapy treatment).
Approximately 15-25% of all breast cancers are human epidermal growth factor receptor 2 (HER2) positive and it has been well known that HER2 overexpression is associated with more aggressive phenotype and poor prognosis with resistance to certain chemotherapeutic agents. Trastuzumab administration as an adjuvant and in metastatic HER2 positive breast cancer is associated with both symptomatic and asymptomatic cardiotoxicity. The incidence of trastuzumab-mediated cardiotoxicity were 27% with antracycline combination and 13% when it was administered with paclitaxel . Pertuzumab, a recombinant humanized monoclonal antibody binding to the HER2 dimerization domain, prevents dimerization of HER2 with other HER receptors (HER3,HER1, and HER4) especially with HER3. Blocking HER2-HER3 dimerization is postulated to be the most clinically relevant action of pertuzumab and this can effectively block her2-mediated cell signaling. Pertuzumab is indicated in combination with trastuzumab and docetaxel for the treatment of patients with HER2-positive metastatic breast cancer who have not received prior anti-HER2 therapy or chemotherapy for metastatic disease. Treatment of breast cancer with pertuzumab plus trastuzumab plus docetaxel as first line treatment until disease progression might be complicated by cardiotoxicity in up to 14.5% of the Patients. Cardinale et al showed that troponin I (TNI) positive identifies trastuzumab-treated patients who are at risk for cardiotoxicity and are unlikely to recover from cardiac dysfunction despite HF therapy. There is very little data about the reversibility and identification of patients at risk for cardiotoxicity of the pertuzumab plus trastuzumab plus docetaxel regimen and of those who will not recover from cardiac dysfunction,this information is crucial. The usefulness of troponin I (TNI) and Brain natriuretic peptide (BNP) in the identification of patients at risk for PT cardiotoxicity and in the prediction of LVEF recovery has never been investigated. based on this background , this study aim is to evaluate the cardiotoxicity of pertuzumab plus trastuzumab plus docetaxel regimen and the application of troponin I (TNI) and Brain natriuretic peptide (BNP) in this setting.