Radiation therapy while important in the management of several diseases, is implicated in the causation of atherosclerosis and other cardiovascular complications. Cancer and atherosclerosis go through the same stages of initiation, promotion, and complication, beginning with a mutation in a single cell. Clinical observations before the 1960s lead to the belief that the heart is relatively resistant to the doses of radiation used in radiotherapy. Subsequently, it was discovered that the heart is sensitive to radiation and many cardiac structures may be damaged by radiation exposure. A significantly higher risk of death due to ischemic heart disease has been reported for patients treated with radiation for Hodgkin's disease and breast cancer. Certain cytokines and growth factors, such as TGF-beta1 and IL-1 beta, may stimulate radiation-induced endothelial proliferation, fibroblast proliferation, collagen deposition, and fibrosis leading to advanced lesions of atherosclerosis. The treatment for radiation-induced ischemic heart disease includes conventional pharmacological therapy, balloon angioplasty, and bypass surgery. Endovascular irradiation has been shown to be effective in reducing restenosis-like response to balloon-catheter injury in animal models. Caution must be exercised when radiation therapy is combined with doxorubicin because there appears to be a synergistic toxic effect on the myocardium. Damage to endothelial cells is a central event in the pathogenesis of damage to the coronary arteries. Certain growth factors that interfere with the apoptotic pathway may provide new therapeutic strategies for reducing the risk of radiation-induced damage to the heart. Exposure to low level occupational or environmental radiation appears to pose no undue risk of atherosclerosis development or cardiovascular mortality. But, other radiation-induced processes such as the bystander effects, abscopal effects, hormesis, and individual variations in radiosensitivity may be important in certain circumstances.
Atherosclerosis is a common disease, primarily of the large arteries, that begins in childhood and progresses with advancing age. Atherosclerosis leads to coronary heart disease, the major cause of death in the United States. Several risk factors affect atherosclerosis, but high LDL cholesterol is the most important risk factor. In addition, high levels of lipoprotein (a) appear to be associated with increased atherosclerosis and myocardial infarction. The level of lipoprotein (a) is genetically determined and is not affected by diet or exercise. Studies on the pathogenesis of atherosclerosis suggest that several steps are involved, including endothelial injury, increased arterial permeability to plasma lipoproteins, smooth muscle cell proliferation, and platelet aggregation. Atherosclerotic plaques are benign neoplasms of the arterial wall that result from the monoclonal proliferation of a single mutated smooth muscle cell. Abnormal proliferation of smooth muscle cells is the key event in the initiation and progression of atherosclerosis. Endothelial injury is another major contributory factor. Many factors associated with an increased risk of cancer are also associated with atherosclerosis. Cancer and atherosclerosis go through the same stages of initiation, promotion, and complication. Both inflammatory and immune reactions play important roles in the progressions of the two diseases. Smooth muscle cells and endothelial cells produce and respond to several cytokines and growth factors, which may influence the initiation, progression, and complication of the atherosclerotic lesions. Many studies have shown that the production of nitric oxide is decreased in atherosclerosis-reduction in the bioavailability of nitric oxide in the arterial wall may lead to leukocyte adhesion and platelet aggregation. It should be noted additionally, nitric oxide is a mutagenic agent involved in the origin of neoplastic diseases. Atherosclerotic plaques express genes for products not found in the normal arterial wall. As with carcinogenesis, there may be more than one mechanism that promotes atherosclerotic lesions and there may be common mechanistic similarities between the two diseases. The purpose of this study is to establish an exploratory scientific hypothesis that will permit the use of standardized toxicological test data to evaluate different chemicals. The companion paper that follows will use a method of relative toxicological potencies to develop tentative risk coefficients based on relative potency. These papers, in combination, provide both a conceptual and a quantitative hypothesis that can be tested with data from forthcoming epidemiological studies or animal test models.
As reviewed in the Part I companion manuscript by Basavaraju and Jones (Arch Environ Contam Toxicol), atherosclerosis and carcinogenesis may share some common mechanisms of toxicological action. On that hypothesis, standardized test data taken from the Registry of Toxic Effects of Chemical Substances (RTECS) were used to compute relative potency factors for chemical compounds associated with increased risk of atherosclerosis to humans. Potencies of the different compounds were computed relative to each of six reference compounds comprised of benzo(a)pyrene, nicotine, cisplatin, adriamycin, estrogen, and 2,3,7,8-tetrachlorodibenzo-p-dioxin. Reference-specific potencies were all converted to a common numerical scale adjusted to unit potency for B(a)P. Because the list of compounds contained several antibiotics, amino acids, hormones, chemotherapeutic agents, polynuclear aromatics, alkaloids, metals, and vitamins, the standardized estimates of potency varied significantly depending on which of the six reference compounds are considered as standards of comparison. For the n - 1 other substances. Estimates of relative potency, risk coefficients, and generalized risk equations are estimated for cigarette smoke condensate, dietary cholesterol, ethanol, and carbon disulfide. From data on atherosclerosis as a result of cigarette smoking, a tentative risk was estimated as Increased Relative Risk = S (mg/kg-day)-1 x dose (mg/kg-day) x RP, where the dose is chronic intake per kilogram of body weight per day, RP is the potency of the compound of interest relative to that of benzo(a)pyrene, and S is 0.83, 0.25, 0.20, or 13 depending on whether cigarette smoke, cholesterol, ethanol, or carbon disulfide epidemiological data were used as a standard of comparison.
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