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Cardiotoxicity may be caused by radiotherapy and/or anticancer agents for many malignancies, adverse effects of some drugs in the context of medical intervention or heavy metal intake, especially during the anticancer therapy. This book intends to bring forward the recent development in toxicities from cancer treatment. It updates the possible mechanisms of cardiotoxicities of some anticancer agents and the suggested prevention and treatment strategies. This book contains many valuable contributions from the researchers in oncology and cardiology as well as the clinicians who are experts in this field.
Holland-Frei Cancer Medicine, Ninth Edition, offers a balanced view of the most current knowledge of cancer science and clinical oncology practice. This all-new edition is the consummate reference source for medical oncologists, radiation oncologists, internists, surgical oncologists, and others who treat cancer patients. A translational perspective throughout, integrating cancer biology with cancer management providing an in depth understanding of the disease An emphasis on multidisciplinary, research-driven patient care to improve outcomes and optimal use of all appropriate therapies Cutting-edge coverage of personalized cancer care, including molecular diagnostics and therapeutics Concise, readable, clinically relevant text with algorithms, guidelines and insight into the use of both conventional and novel drugs Includes free access to the Wiley Digital Edition providing search across the book, the full reference list with web links, illustrations and photographs, and post-publication updates
Anticancer Treatments and Cardiotoxicity: Mechanisms, Diagnostic and Therapeutic Interventions presents cutting edge research on the adverse cardiac effects of both radiotherapy and chemotherapy, brought together by leaders in the field. Cancer treatment-related cardiotoxicity is the leading cause of treatment-associated mortality in cancer survivors and is one of the most common post-treatment issues among survivors of adult cancer. Early detection of the patients prone to developing cardiotoxicity, taking in to account the type of treatment, history and other risk factors, is essential in the fight to decrease cardiotoxic mortality. This illustrated reference describes the most effective diagnostic and imaging tools to evaluate and predict the development of cardiac dysfunction for those patients undergoing cancer treatment. In addition, new guidelines on imaging for the screening and monitoring of these patients are also presented. Anticancer Treatments and Cardiotoxicity is an essential reference for those involved in the research and treatment of cardiovascular toxicity. Provides algorithms essential for the use of imaging, and biomarkers for the screening and monitoring of patients Written by world-leading experts in the field of cardiotoxicity Includes high-quality images, case studies, and test questions Describes the most effective diagnostic and imaging tools to evaluate and predict the development of cardiac dysfunction for those patients undergoing cancer treatment
Cardiotoxicity associated with many cancer drugs is a critical issue facing physicians these days and a huge hurdle that must be overcome for a side effects-free cancer therapy. Survival of cardiac myocytes is compromised upon the exposure to certain chemotherapeutic drugs. Unfortunately, the mechanisms implicated in cardiac toxicity and the pathways governing myocyte survival are poorly understood. The following thesis addresses the mechanisms underlying the cardiotoxicity of two anticancer drugs, doxorubicin (DOX) and Imatinib mesylate (Gleevec). Transcription factor GATA-4, has recently emerged as an indispensable factor in the adult heart adaptive response and cardiomyocyte survival. Therefore, the specific aim of this project was to determine the role of GATA-4, its upstream regulators, as well as partners in survival. A combination of cell and molecular techniques done on in vivo, and ex vivo models were utilized to tackle these issues. In this study, we confirmed the cardiotoxicity of the anticancer drug, Imatinib mesylate and found to be age dependent. GATA-4, already known to be implicated in DOX-induced toxicity, was confirmed as an Imatinib target. At the molecular level, we identified IGF-1 and AKT as upstream regulators of GATA-4. Moreover, we confirmed ZFP260 (PEX-1), a key regulator of the cardiac hypertrophic response, as a GATA-4 collaborator in common prosurvival pathways. Collectively, these results provide new insights on the mechanisms underlying drug-induced cardiotoxicity and raise the exciting possibility that cancer drugs are negatively affecting the same prosurvival pathway(s), in which GATA-4 is a critical component. Therapeutic interventions aimed at enhancing GATA-4 activity may be interesting to consider in the context of treatments with anticancer drugs.
This book describes the relationship of the skin with cardiovascular disease. It details the variety of genetic, autoimmune, metabolic and endocrine factors that link the two disciplines. Recognition of one sign or symptom in dermatology can lead to the investigation and discovery of an important related cardiac condition, the recognition of which is important to prevent cardiovascular complications. Similarly, a cardiac condition may be related to an underlying skin condition that requires treatment. Genetic examples of such instances included within the book include: pseudoxanthoma elasticum, epidermolysis bullosa with desmosome defects and plectin defects; Marfan syndrome; Autoimmune conditions include vasculitis, sarcoidosis, lupus; metabolic conditions include insulin resistance, eruptive xanthomas with hypertriglyceridemias and elevated cholesterol; endocrine disorders include thyroid acropachy with atrial fibrillation; insulin resistance with coronary artery disease and psoriasis or hidradenitis suppurativa. Skin and the Heart reviews the effects of genetic, autoimmune and endocrine diseases with connections between skin and heart. It is therefore a key reference for all practitioners and researchers working in both disciplines.
The application of magnetic resonance spectroscopy (MRS) to the cardiovascular system is a relatively new phenomenon. Its ability to noninvasively examine myocardial metabolism has led to its use to answer basic questions in animal models of normal and diseased myocardium. Extension of these investigations into the realm of human myocardial metabolism has been made possible by the advent of relatively high-field magnets with spectroscopy capabilities and sufficient bore dimensions to allow human studies. While ongoing and future studies promise to enhance our understanding of myocardial metabolism, their success will, in part, depend on a thorough understanding of the technical and biologic aspects of cardiovascular MRS, as well as the current state of research in the many areas encompassed by this discipline. It is with concept that the present monograph has been written. The organization and content should lend this book to both the beginning reader who is interested but not conversant in cardiovascular MRS, as well as to the active investigator who wishes to refer to a volume that deals with the many issues of this field in a concise but complete manner. The monograph is structured with a general overview of the field, followed by a section addressing the technical issues of cardiovascular MRS. The next section is devoted to biologic issues of both normal and abnormal myocardial metabolism, primarily devoted to investigations employing phosphorus-31. This is followed by a section dealing with more specialized issues, generally involving other nuclei such as protons, carbon, and sodium. Finally, the clinical applications of cardiovascular MRS are addressed.
Cardiovascular Toxicity and Therapeutic Modalities Targeting Cardio-Oncology: From Basic Research to Advanced Study analyzes the emerging the field of cardio-oncology, reviewing recent advancements in the field, discussing how to monitor and treat cancer survivors for cardiotoxicity, and identifying potential cardiac side effects in novel cancer therapies. By adopting a translational approach, the book first comprehensively covers the basic science, mechanisms and concepts, which is followed by advanced state-of-art of cardio-oncology. Other sections cover tyrosine kinase inhibitors, Anthracyclines, and biomarkers in cardiotoxicity induced by chemotherapeutic drugs, noninvasive cardiovascular imaging techniques, radiotherapy induced cardiovascular, and more. Anti-cancer treatment is associated with serious cardiovascular adverse events, including arterial and pulmonary hypertension, supraventricular and ventricular arrhythmias, systolic and diastolic cardiac dysfunction and coronary artery disease. Progress in cancer therapy over the past decades improved long-term survival but increased cancer therapy-related cardiotoxicity. Both traditional chemotherapeutic agents and newer therapies have demonstrated profound cardiovascular toxicities. It is important to understand the mechanisms of these toxicities to establish strategies for the prevention and management of complications—arrhythmias, heart failure, and even death. Adopts a translational approach and comprehensively covers the basic science, mechanisms and concepts of cardio-oncology Outlines the current knowledge of biomarkers in cancer therapy-related cardiotoxicity Provides an understanding of the mechanisms of cardiovascular toxicity of various therapies that may lead to the identification of novel targets to reduce vascular complications
Developed as a one-stop reference source for drug safety and toxicology professionals, this book explains why mitochondrial failure is a crucial step in drug toxicity and how it can be avoided. • Covers both basic science and applied technology / methods • Allows readers to understand the basis of mitochondrial function, the preclinical assessments used, and what they reveal about drug effects • Contains both in vitro and in vivo methods for analysis, including practical screening approaches for drug discovery and development • Adds coverage about mitochondrial toxicity underlying organ injury, clinical reports on drug classes, and discussion of environmental toxicants affecting mitochondria
Background: Cardiotoxicity of anti-cancer drugs has emerged as an important factor for cardiovascular complications. There is a growing interest in natural bioactive compounds for targeting the same. Objectives: Synergystic cardio-protective effects of Curcumin were studied in Doxorubicin (Dox) mediated cardiotoxicity. Methodology: Curcumin mediated effects were investigated by various in vitro, in silico and in vivo studies. Various concentration and time dependent cell viability assays were conducted for Dox and Curcumin followed by microscopic, molecular and biochemical assays. In silico docking studies of Curcumin and Dox with cardiac stress molecules were performed. The findings were validated in vivo at transcriptomic and proteomic levels by expression studies. Synergistic effect was also studied on human breast cancer cell line by various assays. Results: We observed that Dox induced cardiotoxicity occurs through ROS over production by exaggerating the inbuilt antioxidants. Interestingly, our study proposes that Curcumin exerts time-dependent opposite responses and validated by docking. Curcumin supplementation in cancer cells exaggerates oxidative stress and results in tumor by modulating pro- and anti-apoptotic biomarkers. In silico docking studies also proposed the signalling pathways operative in curcumin responses. Conclusions: Pre-treatment of Curcumin can suppress the Dox induced cardiotoxicity and supplementing curcumin results in achieving the desired anti-cancerous effect of Dox without compromising its activity thereby reducing dose mediated Dox effects. Hence, Curcumin holds a great potential as future cardio-oncological therapeutics.