Elemental modifications and polycyclic aromatic hydrocarbon metabolism in human fibroblasts

Mineral fibers and particulates represent one of the best documented, economically important, and ubiquitously occurring categories of human carcinogens. Yet, while a wealth of information exists concerning the mechanism of action of physical, chemical, and viral carcinogens, virtually nothing is known relative to the mechanism of action of this economically important class of carcinogenic compounds known as mineral fibers and particulates. While the length and diameter of various forms of asbestos have been associated with both cellular toxicity in vitro and tumor occurrence in vivo, nothing is known about whether or not these same physical properties are responsible for the purported synergistic interaction between cigarette smoking and asbestos exposure relative to the induction of bronchogenic carcinoma. Thus, while the risk of bronchogenic carcinoma for nonsmokers exposed to asbestos appears to be only slightly greater than that for unexposed nonsmoking populations, the risk of occurrence of this same tumor in asbestos workers who also smoke is approximately 100-fold greater than in nonsmoking asbestos workers. The risk of bronchogenic carcinoma is increased approximately 8-fold in asbestos workers who smoke over non-exposed smokers. Since it is clear that cigarette smoke contains over 150 polycyclic aromatic hydrocarbons, some of which are known animal carcinogens, and since other laboratories have reported that metals associated with asbestos redirect the metabolism of these agents, it was of interest to us to investigate the effects of mineral fibers on the metabolism and biochemistry of polycyclic aromatic hydrocarbons.