Mapping and prediction of coal workers' pneumoconiosis with bioavailable iron content in the bituminous coals.Based on the first National Study of Coal Workers' Pneumoconiosis pneumoconiosis (n  'məkō'nēō`sĭs), chronic disease of the lungs. (CWP CWP Coal workers' pneumoconiosis, see there ) and the U.S. Geological Survey database of coal
quality, we show that the prevalence of CWP in seven coal mine regions
correlates with levels of bioavailable iron (BAI n. 1. a language spoken in the Dali region of Yunnan.Noun 1. Bai - the Tibeto-Burman language spoken in the Dali region of Yunnan Baic ) in the coals from that particular region (correlation coefficient Correlation Coefficient A measure that determines the degree to which two variable's movements are associated. The correlation coefficient is calculated as: r = 0.94, p < 0.0015). CWP prevalence is also correlated with contents of pyritic sulfur (r = 0.91, p < 0.0048) or total iron (r = 0.85, p < 0.016) but not with coal rank (r = 0.59, p < 0.16) or silica (r = 0.28, p < 0.54). BAI was calculated using our model, taking into account chemical interactions of pyrite, sulfuric acid sulfuric acid, chemical compound, H2SO4, colorless, odorless, extremely corrosive, oily liquid. It is sometimes called oil of vitriol. Concentrated Sulfuric Acid , calcite calcite (kăl`sīt), very widely distributed mineral, commonly white or colorless, but appearing in a great variety of colors owing to impurities. , and total iron. That is, iron present in coals can become bioavailable by pyrite oxidation, which produces ferrous sulfate ferrous sulfate or iron (II) sulfate, chemical compound, FeSO4. It is known as the monohydrate, FeSO4·H2O; the tetrahydrate, FeSO4·4H2O; the pentahydrate, FeSO4 and sulfuric acid. Calcite is the major component in coals that neutralizes the available acid and inhibits iron's bioavailability bioavailability /bio·avail·a·bil·i·ty/ (bi?o-ah-val?ah-bil´i-te) the degree to which a drug or other substance becomes available to the target tissue after administration. bi·o·a·vail·a·bil·i·ty n. . Therefore, levels of BAI in the coals are determined by the available amounts of acid after neutralization neutralization, chemical reaction, according to the Arrhenius theory of acids and bases, in which a water solution of acid is mixed with a water solution of base to form a salt and water; this reaction is complete only if the resulting solution has neither acidic nor of calcite and the amount of total iron in the coals. Using the linear fit of CWP prevalence and the calculated BAI in the seven coal mine regions, we have derived and mapped the pneumoconiotic potencies of 7,000 coal samples. Our studies indicate that levels of BAI in the coals may be used to predict coal's toxicity, even before large-scale mining. Key words: bioavailable iron, calcite, coal, chronic obstructive pulmonary disease chronic obstructive pulmonary disease n. Abbr. COPD A chronic lung disease, such as asthma or emphysema, in which breathing becomes slowed or forced. , COPD COPD chronic obstructive pulmonary disease. COPD abbr. chronic obstructive pulmonary disease Chronic obstructive pulmonary disease (COPD) , pneumoconiosis. doi:10.1289/ehp.7679 available via http://dx.doi.org/[Online 15 April 2005] ********** Coal remains a major energy resource worldwide. In the United States, > 50% of electricity is generated in coal-fired power plants. Recent debate in the United States has focused on increasing coal use. In fact, energy costs from a new coal power plant are low, between $0.035 and $0.04/kW-hr (Jacobsen and Masters 2001). However, coal mining causes environmental problems such as acid mine drainage Acid mine drainage (AMD), or acid rock drainage (ARD), refers to the outflow of acidic water from (usually) abandoned metal mines or coal mines. However, other areas where the earth has been disturbed (e.g. , whereas the inhaled coal particles at the work place may lead to the development of coal workers' pneumoconiosis (CWP; Castranova and Vallyathan 2000; Demchak et al. 2004). According to the National Institute of Occupational Safety and Health The National Institute for Occupational Safety and Health (NIOSH) is the federal agency responsible for conducting research and making recommendations for the prevention of work-related injury and illness. (NIOSH NIOSH National Institute for Occupational Safety & Health, see there NIOSH Recommendations for Safety & Health Standards Agent NIOSH REL*/OSHA PEL† Health effects 2003), CWP deaths accounted for half of the pneumoconiosis deaths during the 10-year period from 1990 to 1999. Coal mining can also increase the risk of developing asthma and chronic obstructive pulmonary disease (COPD), such as emphysema emphysema (ĕmfĭsē`mə), pathological or physiological enlargement or overdistention of the air sacs of the lungs. A major cause of pulmonary insufficiency in chronic cigarette smokers, emphysema is a progressive disease that commonly and chronic bronchitis chronic bronchitis n. Inflammation of the bronchial mucous membrane, characterized by cough, hypersecretion of mucus, and expectoration of sputum over a long period of time and associated with increased vulnerability to bronchial infection. (Attfield and Kuempel 2003; Ruckley et al. 1984; Soutar et al. 2004). Among the occupations listed by the U.S. Census industry code, coal mining is the highest risk job associated with asthma and COPD death, with a proportionate mortality proportionate mortality Epidemiology The proportion of deaths in a specified population over a period of time attributable to different causes; each cause is expressed as a percentage of all deaths; the sum of causes must add to 100%. Cf Mortality. ratio of 1.98 [95% confidence interval confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. (CI), 1.84-2.12, adjusted for age, sex, and race), compared with the second highest risk job of trucking service of 1.29 (95% CI, 1.22-1.37) (NIOSH 2003). Federal "black lung black lung: see pneumoconiosis. " program payments totaled > $1.5 billion for nearly 190,000 beneficiaries in 1999. Health and environmental costs, such as occupational lung disease Main Article COPD Occupational lung diseases are a specific branch of occupational diseases concerned primarily with work related exposures to harmful substances, be they dusts or gases, and the subsequent pulmonary disorders that may occur as a result. compensation, can bring the total cost from $0.035-0.04/kW-hr to as high as $0.0556-0.083/kW-hr (Jacobson and Masters 2001). If we can predict the toxicity of coal before mining, we may be able to develop screening and prevention programs that carefully monitor early adverse effects and, thus, reduce health care costs related to the coal use. Coal is an aggregate of heterogeneous substances composed of organic and inorganic materials. The four major coal types ranked in order of increasing heat value are lignite lignite (lĭg`nīt) or brown coal, carbonaceous fuel intermediate between coal and peat, brown or yellowish in color and woody in texture. , subbituminous, bituminous bi·tu·mi·nous adj. 1. Like or containing bitumen. 2. Of or relating to bituminous coal. Adj. 1. bituminous - resembling or containing bitumen; "bituminous coal" , and anthracite anthracite (ăn`thrəsīt'): see coal. anthracite or hard coal Coal containing more fixed carbon than any other form of coal and the lowest amount of volatile (quickly evaporating) material, giving it the . The inorganic portion of coal can range from a few percent to > 50% (by weight) and is composed of phyllosilicates (kaolinite kaolinite (kā`əlĭnīt), clay mineral crystallizing in the monoclinic system and forming the chief constituent of china clay and kaolin. , illite Illite is a non-expanding, clay-sized, micaceous mineral. Illite is a phyllosilicate or layered silicate. Structurally illite is quite similar to muscovite or sericite with slightly more silicon, magnesium, iron, and water and slightly less tetrahedral aluminium and interlayer , etc.), quartz, carbonates, sulfides, sulfates, and other minerals (Meyers 1982). In general, aluminum and iron are the main metals in the coals. Arsenic, nickel, zinc, cadmium, cobalt, and copper are trace metals that represent only a very small fraction of the mineral matter (Finkelman 1995). Iron is the best-known transition metal capable of producing oxidants through Fenton, Haber-Weiss, or autoxidation autoxidation /au·tox·i·da·tion/ (aw-tok?si-da´shun) auto-oxidation. au·tox·i·da·tion n. See autooxidation. reactions (Huang 2003). However, not all iron compounds in the coals are bioavailable for oxidant oxidant /ox·i·dant/ (ok´si-dant) the electron acceptor in an oxidation-reduction (redox) reaction. ox·i·dant n. See oxidizer. formation and subsequent adverse health effects. We have previously defined bioavailable iron (BAI) as the iron released in 10 mM phosphate solution, pH 4.5, which mimics the phagolysosomes of cells (Huang et al. 1998). Based on 30 coal samples from three coal mine regions, we have shown that levels of BAI in the coals correlated with the prevalence of CWP, and it was the BAI in the coals that transactivated the two important transcription factors of activator protein-1 and nuclear factor of activated T cells T cells A type of white blood cell produced in the thymus gland. T cells are an important part of the immune system. Infants born with an underdeveloped or absent thymus do not have a normal level of T cells in their blood. (Huang et al. 2002; Zhang et al. 2002; Zhang and Huang 2002). The purpose of this study was to validate our hypothesis regarding BAI using a model based on various chemical interactions in the mixed coal dusts. Because it is impossible to obtain and measure BAI in all coal samples from the period when epidemiologic studies were performed during 1969 and 1971, we used the the U.S. Geological Survey (USGS USGS United States Geological Survey (US Department of the Interior) ) database of coal quality (Bragget al. 1998) for calculating BAI in each coal mine region. The USGS database is the largest publicly available database containing information on the chemistry and properties of U.S. coals. For the calculation of BM for each individual coal, molar amounts of pyritic sulfur ([S.sub.py]) per gram of dry coal, as well as sulfate sulfate, chemical compound containing the sulfate (SO4) radical. Sulfates are salts or esters of sulfuric acid, H2SO4, formed by replacing one or both of the hydrogens with a metal (e.g., sodium) or a radical (e.g., ammonium or ethyl). , calcium oxide calcium oxide, chemical compound, CaO, a colorless, cubic crystalline or white amorphous substance. It is also called lime, quicklime, or caustic lime, but commercial lime often contains impurities, e.g., silica, iron, alumina, and magnesia. (CaO), and total iron were taken into account. For correlation with CWP prevalence, other factors that were previously thought to contribute to CWP were also incorporated, such as coal rank or quartz. CWP prevalence in seven coal mine regions has been shown to be significantly correlated with the levels of BAI from the same region. Using the model that we developed, pneumoconiotic potencies of 7,000 coal samples were derived and mapped in the present study. Materials and Methods Coal data and samples. Our hypothesis has been that BAI is the active component in the coals that induces CWP. If that proves to be the case, then the differences in the levels of BAI in the coals may be responsible for the observed regional differences in the prevalence of CWP. To test our hypothesis, we used CWP prevalence data from the first National Study of Coal Workers' Pneumoconiosis (NSCWP) (Morgan et al. 1973) as well as physicochemical physicochemical /phys·i·co·chem·i·cal/ (fiz?i-ko-kem´ik-il) pertaining to both physics and chemistry. phys·i·co·chem·i·cal adj. 1. Relating to both physical and chemical properties. data from the USGS coal quality database (Bragg et al. 1998). In 1969, the first round of the NSCWP selected 31 coal mines, of which 29 were bituminous and two were anthracite mines (Morgan et al. 1973). Eight mines were located in Pennsylvania (PA; two anthracite, six bituminous); nine in West Virginia (WV); three in Kentucky (KY); two each in Virginia (VA), Alabama (AL), Illinois, and Utah (UT); and one each in Ohio (OH), Indiana (IN), and Colorado (CO). Participation in the first round was 90.5%. A total of 9,076 miners were fully examined, of which 8,553 were bituminous workers and 523 were anthracite workers. Because the properties of anthracite are different from bituminous coals and the number of anthracite miners was small, we excluded the two anthracite mines in the PA coal mine region from the present study. Only bituminous coals, including the six in PA, were used for BM calculation and its correlation with CWP prevalence. Based on the names of the coal mines, counties, and states, we searched the USGS coal quality database (Bragg et al. 1998) and matched 94 coal samples from 24 coal mines within seven states. These are bituminous coals obtained from mines within the same state, county, and coal seam as those samples used in the first NSCWP (Bragg et al. 1998). Most of the samples in the USGS database were collected in 1975-1985. BAI calculation. BAI consists mainly of water-soluble iron, such as ferrous and ferric sulfate, which can be originally present in the coals or can be obtained by the oxidation of pyrite (Fe[S.sub.2]). Another possible source of BAI is acid solubilization of siderite siderite (sĭd`ərīt) or chalybite (kăl`ĭbīt), a mineral, varying in color from brown, green, or gray to black and occurring in nature in massive and crystalline form. (FeC[O.sub.3]) or ferrous silicate silicate, chemical compound containing silicon, oxygen, and one or more metals, e.g., aluminum, barium, beryllium, calcium, iron, magnesium, manganese, potassium, sodium, or zirconium. Silicates may be considered chemically as salts of the various silicic acids. (FeSi[O.sub.3]). Using the USGS coal database (Bragg et al. 1998), we have calculated levels of BAI in each coal. Considering that most BAI originates from Fe[S.sub.2] oxidation (Huggins et al. 1983), we used the following formula for the calculations: [1] 2Fe[S.sub.2] + 702 + 2[H.sub.2]0 [right arrow] 2FeS[O.sub.4] + 2[H.sub.2]S[O.sub.4] One mole Fe[S.sub.2] will produce 1 mol BAI as ferrous sulfate (FeS[O.sub.4]) and 1 mol sulfuric acid ([H.sub.2]S[O.sub.4]). However, levels of Fe[S.sub.2] in the USGS coal database (Bragg et al. 1998) were not measured directly. Because only [S.sub.py] content is available in the database, reaction 1 shows that 1 mol Spy will produce 0.5 mol BM and 0.5 mol [H.sub.2]S[O.sub.4]. Previous studies have shown that BAI is stable only in an acidic environment (Huang et al. 1994). If calcite (CaC[O.sub.3]) is present in the coal, CaC[O.sub.3] will consume the acid and neutralize the pH as follows: [2] CaC[O.sub.3] + [H.sub.2]S[O.sub.4] [right arrow] CaC[O.sub.4] + [H.sub.2]O + C[O.sub.2] Increasing the pH would facilitate ferrous and ferric ferric (fĕr`ĭk), iron in the +3 valence state. See ferrous. ion oxidation to goethite goethite Widespread iron hydroxide mineral, α-FeO(OH), the most common ingredient of iron rust. In terms of relative abundance, it is second only to hematite (α-Fe2O3) among iron oxides. (FeOOH), which is water insoluble and thus not bioavailable for redox redox (rē`dŏks): see oxidation and reduction. reactions (Lowson 1982; Singer and Stumm 1969). Therefore, no BM will accumulate when CaC[O.sub.3] is present. If CaC[O.sub.3] is absent in the coals, [H.sub.2]S[O.sub.4] produced from reaction 1 would solubilize sol·u·bi·lize v. To make substances such as fats soluble in water by the action of a detergent or similar agent. other iron compounds (e.g., FeC[O.sub.3]) and release more BAI as follows: [3] FeC[O.sub.3] + [H.sub.2]S[O.sub.4] [right arrow] Fe[S.sub.4] + [H.sub.2]O + C[O.sub.2] Based on the above chemical reactions, we concluded that the total available molar amounts of [H.sub.2]S[O.sub.4] in a given amount of coal would be as follows: [[H.sub.2]S[O.sub.4]] = [one-half[S.sub.py] + sulfate - CaC[O.sub.3]]. If [[H.sub.2]S[O.sub.4]] [less than or equal to] 0, the acid is completely consumed by CaC[O.sub.3] and, concomitantly, iron will be oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. . Therefore, there will be no BM in that coal. If [[H.sub.2]S[O.sub.4]] > 0, the excess acid would stabilize BAI and, possibly, also leach out other iron compounds, such as Fe[S.sub.3], thus releasing additional BM. Based on the USGS coal database, Spy and sulfates as percentages of coal are available for calculations. CaC[O.sub.3] and Fe[S.sub.3] in the coals were not measured. However, levels of CaO and the total amount of iron (shown as [Fe.sub.2][O.sub.3]) were measured in high-temperature ashes of the coals; the ash yield in the coal is available from the USGS database. We assumed that the CaO was all derived from CaC[O.sub.3] and the iron was derived from Fe[S.sub.2], two of the most common minerals in coal, thus maximizing the CaC[O.sub.3] and Fe[S.sub.2] estimates. Because 1 mol CaO is formed by the decomposition of 1 mol CaC[O.sub.3] at high temperature, this allowed us to use the same molar amounts of CaO as measures of CaC[O.sub.3]. We then calculated the millimolar amounts of [S.sub.py] and sulfates per 100 g dry coal in each individual coal. The millimolar amounts of CaO and total iron ([Fe.sub.2][O.sub.3]) per 100 g dry coal were also calculated after taking into consideration the ash yield in each individual coal. Results Table 1 shows that marked regional differences in the prevalence of CWP existed, with the disease being most common in bituminous miners of PA [cumulated prevalence of 45.4%, including diseases of categories 1, 2, 3 (Henry 2002; Jacobsen 1991), and progressive massive fibrosis Progressive Massive Fibrosis is also known as Complex Pneumoconiosis. It is a disease that almost entirely affects coal miners. The disease arises firstly through the deposition of coal dust within the lung, and then through the body's immunological reactions to the dust. ] and least common in miners of CO (4.6%), after adjusting for age and years spent underground (Morgan et al. 1973). The follow-up studies at the same mines (in 1972-1975, 1977-1981, 1985-1988, and 1996-2002) have shown that the overall prevalence of CWP decreased in the United States because of the lowered dust levels, but the regional difference persisted with a greater risk in eastern coal miners (PA and WV) than in western coal miners (UT and CO) (Attfield and Morring 1992a; Attfield and Seixas 1995; Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. 2003; Goodwin and Attfield 1998). After taking into consideration the slight differences present in exposure concentration or mining techniques, as well as the X-ray reader variation or changes in X-ray standard, these epidemiologic results indicate that physicochemical characteristics of the coals responsible for toxicity are different in the eastern and western states (Attfield and Morring 1992a). Table 1 also summarizes the molar ratio of C:H as one of the indicators of coal rank, [S.sub.py], sulfate, silicon dioxide silicon dioxide: see silica. (SiO2) A hard, glassy mineral found in such materials as rock, quartz, sand and opal. In MOS chip fabrication, it is used to create the insulation layer between the metal gates of the top layer and the silicon elements below. content, CaO, iron oxide The material used to coat the surfaces of magnetic tapes and lower-capacity disks. , arsenic, and nickel (mmol/100 g dry coal) from the USGS coal quality database (Bragg et al.). The sample sizes varied from one state to another because of the availability of coal samples in the USGS database. There were also wide variations on physicochemical characteristics, as reflected by large SDs, which were probably due to the heterogeneity of coal samples. Levels of coal rank and silica content, two parameters that were previously thought important in contributing to CWP development, do not vary as much as CWP prevalence does from east to west (Table 1). CaO, a product from the decomposition of CaC[O.sub.3] in the high-temperature ashes of the coals, does not differ much from one state to another. In general, levels of Spy, total iron, arsenic, and nickel are higher in the eastern coal mine regions (PA, OH, KY, WV) than in western coal mine regions (UT and CO). The average levels of total [H.sub.2]S[O.sub.4] (1/2 [S.sub.py] + sulfate), the amount of acid available for solubilization of other iron compounds (1/2 [S.sub.py] + sulfate - CaO), total iron, and BAI in each coal mine region are summarized in Table 2. In calculating BAI, we discovered that the amount of BM in the coal should be equal to the lesser value between the amount of available acid (1/2 [S.sub.py] + S[O.sub.4.sup.2-] - CaO) and [Fe.sub.2][O.sub.3]: a) if the coal has an excessive amount of acid and a limited amount of iron, BAI will be limited by the amount of iron present; and b) if the coal has less acid but more iron present, BAI will then be limited by the amount of acid because excess iron cannot be solubilized and therefore cannot become bioavailable. Table 2 shows the average levels of BAI (mmol/100 g dry coal) from seven states with corresponding CWP prevalence reported in the first NSCWP (Morgan et al. 1973). Table 3 shows a very good correlation between CWP prevalence and BAI (correlation coefficient r = 0.94; 95% CI, 0.66-0.999; p < 0.0015), as well as with Spy (r = 0.91; 95% CI, 0.35-0.99; p < 0.0048) and total iron (r = 0.85; 95% CI, 0.20-0.97; p < 0.016), but not significantly with coal rank (r = 0.59; 95% CI, -0.26 to 0.91; p < 0.16) or silica (r = 0.28; 95% CI, -0.55 to 0.82; p < 0.54). No association of CWP with CaO itself was observed (r = -0.18; 95% CI,-0.78 to 0.60; p < 0.69). The relationship between CWP and BAI is well described by a linear model. Figure 1 displays the fitted line and a scatterplot of the data tagged by the coal mine region of its origin. Based on the levels of BAI in each coal that we calculated, we derived the pneumoconiotic potency in 7,000 coal samples collected by the USGS. Figure 2 shows that there is a geographic distribution of coals with different levels of BAI and therefore possibly different pneumoconiotic potencies. For example, in the western states, most coals do not have BAI, which may pose less risk to coal miners (shown in green, Figure 2). In the eastern states, there is a trend for possibly high risk coals (black and gray), ranging from PA to OH to WV and KY. There is also an apparent trend of low-risk coal (blue and green) from WV to TN to AL. Because CWP prevalence was much higher in the first round of the NSCWP (Morgan et al. 1973) than in the current epidemiologic data, the prevalence of CWP in the map is probably overestimated, in part due to reduced dust exposure. However, the indication of the relative risk of CWP in coal mining in various coal mine regions may still be valid and useful for CWP prediction. For example, today most of U.S. coals come from Wyoming, a state that was not studied in the first round of NSCWP but has a low CWP prevalence predicted, as shown in Figure 2. [FIGURES 1-2 OMITTED] Discussion CWP is one of the occupational diseases that has been most studied by epidemiologists. In the United States, Great Britain, France, and Germany, the prevalence and severity of CWP have been shown to differ markedly among coal mines despite exposures comparable with respirable respirable /res·pir·a·ble/ (re-spir´ah-b'l) 1. suitable for respiration. 2. small enough to be inhaled. res·pi·ra·ble adj. 1. Fit for breathing, as air. dust. In the United States, there has been a decline in the prevalence from east to west, the disease being most common in PA coal miners and least common in coal miners from UT. In France, coal miners of Provence never had reported CWP (0%), and the prevalence of CWP in coal miners of Nord Pas de Calais Pas de Ca·lais See Strait of Dover. Noun 1. Pas de Calais - the strait between the English Channel and the North Sea; shortest distance between England and the European continent Strait of Calais, Strait of Dover was 24% (Amoudru 1987). In Great Britain, the proportional mortality ratios for CWP varied from 135 in Leicestershire county to 3,825 in South Glamorgan county (Coggon et al. 1995). These epidemiologic results indicate that physicochemical characteristics of the coals responsible for toxicity may be different from one coal mine region to another. This fact allowed us to correlate certain physicochemical characteristics of coals with the epidemiologic results. In the present study we found a significant correlation between CWP prevalence and levels of BM in the coals. FeS2, a typical contaminant contaminant /con·tam·i·nant/ (kon-tam´in-int) something that causes contamination. contaminant something that causes contamination. in coals, readily undergoes oxidation and forms BAI and acid. The formed acid in the coal mines causes acid mine drainage in the environment, and CaCO3 is used for its treatment (Aziz et al. 2004; Cravotta 2003; Demchak et al. 2004). Burning of [S.sub.py]-containing coal produces sulfuric dioxide (S[O.sub.2]), a major component of acid rain (Carmichael et al. 2002; Srivastava and Jozewicz 2001). BAI, a fraction of total iron, can catalyze oxidant formation and lead to oxidative lung damage. CaC[O.sub.3], a mineral existing only in certain coals, such as those in the western coal mines, can oxidize oxidize /ox·i·dize/ (ok´si-diz) to cause to combine with oxygen or to remove hydrogen. ox·i·dize v. 1. To combine with oxygen; change into an oxide. 2. BAI and make iron less bioavailable for adverse health effects (Huang et al. 1998, 2002; Zhang et al. 2002; Zhang and Huang 2002). Therefore, our results indicate that certain minerals in the coals can interact and thus contribute to different levels of BAI. This might provide an explanation for the observed regional differences in the prevalence of CWP and the associated COPD. Increasing evidence demonstrates that iron present in the coal fly ash, asbestos, or urban particles can lead to increased oxidant, ferritin ferritin /fer·ri·tin/ (-i-tin) the iron-apoferritin complex, one of the chief forms in which iron is stored in the body. fer·ri·tin n. , and cytokine Cytokine Any of a group of soluble proteins that are released by a cell to send messages which are delivered to the same cell (autocrine), an adjacent cell (paracrine), or a distant cell (endocrine). formation (Chao et al. 1994; Fang and Aust 1997; Smith and Aust 1997; Smith et al. 2000). These studies support our hypothesis that BAI may be responsible for coal-dust-induced lung injury. [S.sub.py] and total iron also significantly correlate with CWP prevalence in the present study (Table 3), suggesting that [S.sub.py] and total iron levels, which are available in the USGS coal database (Bragg et al. 1998), may be used as simple indexes for predicting coal's toxicity. However, we have previously noticed that samples from the coal mines of Provence, France, had high levels of Fe[S.sub.2] (Huang et al. 1994), but coal workers in the Provence coal mine region do not have reported CWP (Amoudru 1987). It is this observation that leads us to search for other factor(s) that may contribute to or inhibit CWP development. In fact, the coals of Provence contain large amounts of CaC[O.sub.3] ([greater than or equal to] 10% wt/wt). By suspending these coals in acid (100 mM [H.sub.2]S[O.sub.4]), no BAI was released. Therefore, it may not be coincidental that the coals having no BAI did not report CWP in miners working in the coal mine regions. Similarly, coals from UT did not release iron at pH 4.5 mimicking phagalososomes but released iron in 50 mM HCl. These results suggest that not all iron compounds are bioavailable. In fact, the presence of CaC[O.sub.3] in certain coals makes iron less bioavailable. Our results indicate that oxidation of Fe[S.sub.2] and subsequent neutralization of acid by CaC[O.sub.3] most likely determine the levels of BAI in the coal dusts. This is further supported by the improved correlation between CWP prevalence and BM over the correlation with available acid (1/2 [S.sub.py] + S[O.sub.4.sup.2-] - CaO) or total iron. From a chemical point of view, CaC[O.sub.3] is more basic than FeC[O.sub.3], consuming acid first before FeC[O.sub.3]. Therefore, CaC[O.sub.3] limits iron's bioavailability. This should not be surprising because, in nutrition, calcium carbonate calcium carbonate, CaCO3, white chemical compound that is the most common nonsiliceous mineral. It occurs in two crystal forms: calcite, which is hexagonal, and aragonite, which is rhombohedral. supplements depress iron's bioavailability (Cook et al. 1991; Prather and Miller 1992; Wienk et al. 1996). CWP, which was originally thought to be a variant of silicosis silicosis (sĭlĭkō`sĭs), occupational disease of the lungs caused by inhalation of free silica (quartz) dust over a prolonged period of time. , results from the inhalation of coal mine dust that usually contains relatively small amounts of free crystalline silica (quartz) (Borm and Tran 2002; Castranova and Vallyathan 2000). Coal rank was found to play a role, because CWP risk increases with coal rank (Attfield and Morring 1992b; Maclaren et al. 1989). Laboratory coal breakage studies have shown a positive correlation with the amount of respirable-size particles found in the product increasing with coal rank (Moore and Bise 1984). It has been suggested that higher rank coals with a higher electrostatic charge on breakage may contribute to the increased incidence of CWP in the high-rank coal regions (Page and Organiscak 2000). However, a correlation between coal rank and cell cytotoxicity has not yet been established in biologic studies (Christian and Nelson 1978; Christian et al. 1979). In the present study, no significant correlation between CWP prevalence and coal rank or silica was observed (r = 0.59, p < 0.16 for coal rank and r = 0.28, p < 0.54 for silica). Based on the present study using the calculated model of BM, we believe that it may be possible to predict which coal is likely to be toxic, even before large-scale mining. However, this study is far from concluding the cause-and-effect relationship between BM and CWP and the associated COPD development. Further studies on the role of BM in cell and lung injury, as well as the protective role of CaC[O.sub.3] in inhibiting BAI and the associated injuries, are still needed. Other limits of the present study are a) noninclusion of anthracite coals for the correlation study but use of only bituminous coals, which restricts the usefulness of comparing BM with coal rank or extrapolation (mathematics, algorithm) extrapolation - A mathematical procedure which estimates values of a function for certain desired inputs given values for known inputs. If the desired input is outside the range of the known values this is called extrapolation, if it is inside then to anthracite coals; b) incomplete coal samples from all states as in the first NSCWP (Morgan et al. 1973), and no recognition of many surface coal mines in the western states (e.g., Wyoming and Texas) where CWP may be less likely to occur than in underground coal mines; and c) lack of consideration of coal particle sizes, effects of other transition metals that may become bioavailable, and effects of phagolysosomes of cells in contributing to acid solubilization of iron in the coals. REFERENCES Amoudru C. 1987. Les pneumoconioses--dimension actuelle des problemes. Colloque INSERM INSERM Institut National de la Santé et de la Recherche Médicale (French Institute of Health and Medical Research) 155:3-40. Attfield MD, Kuempel ED. 2003. Pneumoconiosis, coalmine dust and the PFR. Ann Occup Hyg 47:525-529. Attfield MD, Morring K. 1992a. The derivation of estimated dust exposures for U.S. coal miners working before 1970. Am Ind Hyg Assoc J 53:248-255. Attfield MD, Morring K. 1992b. An investigation into the relationship between coal workers' pneumoconiosis and dust exposure in U.S. coal miners. Am Ind Hyg Assoc J 53:486-492. Attfield MD, Seixas NS. 1995. Prevalence of pneumoconiosis and its relationship to dust exposure in a cohort of U.S. bituminous coal miners and ex-miners. Am J Ind Med 27:137-151. Aziz HA, Yusoff MS, Adlan MN, Adnan NH, Alias S. 2004. Physico-chemical removal of iron from semi-aerobic landfill leachate leach·ate n. A product or solution formed by leaching, especially a solution containing contaminants picked up through the leaching of soil. by limestone filter. Waste Manag 24:353-358. Borm PJ, Tran L. 2002. From quartz hazard to quartz risk: the coal mines revisited. Ann Occup Hyg 46:25-32. Bragg LJ, Oman JK, Tewalt SJ, Oman CL, Rega NH, Washington PM, et al. 1998. U.S. Geological Survey Coal Quality (COALQUAL) Database. U.S. Geological Survey Open-File Report 97-134. Reston, VA:U.S. Geological Survey, Available: http://energy.er.usgs.gov/prodUcts/databases/coalqual/ index.htm [accessed 9 June 2005]. Carmichael GR, Streets DG, Calori 6, Amann M, Jacobson MZ, Hansen J, et al. 2002. Changing trends in sulfur emissions in Asia: implications for acid deposition, air pollution, and climate. Environ Sci Techno 136:4707-4713. Castranova V, Vallyathan V. 2000. Silicosis and coal workers' pneumoconiosis. Environ Health Perspect 108(suppl 4):675-684. Centers for Disease Control and Prevention. 2093. Pneumoconiosis prevalence among working coal miners examined in federal chest radiograph radiograph /ra·dio·graph/ (-graf?) the film produced by radiography. ra·di·o·graph n. surveillance programs--United States, 1996-2002. MMWB Morb Mortal Wkly Rep 52:336-340. Chao CC, Lund LG, Zinn KR, Aust AE. 1994. Iron mobilization from crocidolite crocidolite or blue asbestos Gray-blue to green, highly fibrous (asbestiform) form of the amphibole mineral riebeckite. It has higher tensile strength than chrysotile asbestos. asbestos by human lung carcinoma cells. Arch Biochem Biophys 314:384-391. Christian RT, Nelson J. 1978. Coal: response of cultured mammalian cells corresponds to the prevalence of coal workers pneumoconiosis. Environ Res 15:232-241. Christian RT, Nelson JB, Cody TE, Larson E, Bingham E. 1979. Coal workers' pneumoconiosis: in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. study of the chemical composition and particle size as causes of the toxic effects of coal. Environ Res 29:358-365. Coggon D, Inskip H, Winter P, Pannett B. 1995. Contrasting geographical distribution of mortality from pneumoconiosis and chronic bronchitis and emphysema in British coal miners. Occup Environ Med 52:554-555. Cook JD, Dassenko SA, Whittaker P. 1991. Calcium supplementation calcium supplementation Metabolism The addition of Ca2+ to the diet, usually in the form of calcium carbonate : effect on iron absorption. Am J Clin Nutr 53:106-111. Cravotta CA III. 2003. Size and performance of anoxic an·ox·i·a n. 1. Absence of oxygen. 2. A pathological deficiency of oxygen, especially hypoxia. [an- + ox(o)- + -ia1. limestone drains to neutralize acidic mine drainage. J Environ Qual 32:1277-1289. Demchak J, Skousen J, McDonald LM. 2004. Longevity of acid discharges from underground mines located above the regional water table. J Environ Qua133:656-668. Fang R, Aust AE. 1997. Induction of ferritin synthesis in human lung epithelial cells Epithelial cells Cells that form a thin surface coating on the outside of a body structure. Mentioned in: Corneal Transplantation treated with crocidolite asbestos. Arch Biochem Biophys 340:369-375. Finkelman RB. 1995. Modes of occurrence of environmentally-sensitive trace elements Trace elements A group of elements that are present in the human body in very small amounts but are nonetheless important to good health. They include chromium, copper, cobalt, iodine, iron, selenium, and zinc. Trace elements are also called micronutrients. in coal. In: Environmental Aspects of Trace Elements (Swaine DJ, Goodarzi F, eds). Boston: Kluwer Academic Publishers, 24-50. Goodwin S, Atffield M. 1998. Temporal trends in coal workers' pneumoconiosis prevalence. Validating the National Coal Study results. J Occup Environ Med 40:1065-1071. Henry DA. 2002. International Labor Office Classification System in the age of imaging: relevant or redundant. J Thorac Imaging 17(3):179-188. Huang C, Li J, Zhang Q, Huang X. 2002. Role of bioavailable iron in coal dust-induced activation of activator protein-1 and nuclear factor of activated T cells: difference between Pennsylvania and Utah coal dusts. Am J Respir Cell Mol Biol 27:568-574. Huang X. 2003. Iron overload Iron overload A side effect of frequent blood transfusions in which the body accumulates abnormally high levels of iron. Iron deposits can form in organs, particularly the heart, and cause life-threatening damage. and its association with cancer risk in humans: evidence for iron as a carcinogenic carcinogenic having a capacity for carcinogenesis. metal. Mutat Res 533:153-171. Huang X, Fournier J, Koenig K, Chen LC. 1998. Buffering capacity buffering capacity, n the body's ability to neutralize the acids that play a role in the demineralization of teeth; may be enhanced by eating firmly textured foods, which improve chewing and stimulate the flow of saliva. of coal and its acid-soluble Fe2+ content: possible role in coal workers' pneumoconiosis. Chem Res Toxicol 11:722-729. Huang X, Zalma R, Pezerat H. 1994. Factors that influence the formation and stability of hydrated hy·drat·ed adj. Chemically combined with water, especially existing in the form of a hydrate. Adj. 1. hydrated - containing combined water (especially water of crystallization as in a hydrate) hydrous ferrous sulfate in coal dusts. Possible relation to the emphysema of coal miners. Chem Res Toxicol 7:451-457. Huggins FE, Huffman GP, Lin MC. 1983. Observations on low-temperature oxidation of minerals in bituminous coals. Int J Coal Geol 3:157-182. Jacobsen M. 1991. The International Labour Office Classification: use and misuse. Ann NY Acad Sci 643:100-107. Jacobson MZ, Masters GM. 2001. Energy. Exploiting wind versus coal. Science 293:1438. Lowson RT. 1982. Aqueous oxidation of pyrite by molecule of oxygen. Chem Rev 82:461-497. Maclaren WM, Hurley JF, Collins HP, Cowie AJ. 1989. Factors associated with the development of progressive massive fibrosis in British coalminers: a case-control study case-control study, n an investigation employing an epidemiologic approach in which previously existing incidents of a medical condition are used in lieu of gathering new information from a randomized population. . Br J Ind Med 46:597-607. Meyers RA. 1982. Coal Structure. New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of : Academic Press. Moore MP, Bise CJ. 1984. The relationship between the hard-grove grindability index and the potential for respirable dust generation. In: Proceedings of the Coal Mine Dust Conference, 8-10 October, Morgantown, WV:West Virginia University West Virginia University, mainly at Morgantown; coeducational; land-grant and state supported; est. and opened 1867 as an agricultural college, renamed 1868. , 250-255. Morgan WKC WKC Westminster Kennel Club WKC World Kendo Championships WKC Western Knight Center for Specialized Journalism (Los Angeles, CA) WKC World Krak Cartel (band) WKC Watch-Keeping Certificate , Burgess DB, Jacobson G, O'Brien RJ, Pendergrass E, Reger RB, et al. 1973. The prevalence of coal workers' pneumoconiosis in US coal miners. Arch Environ Health 27:221-230. NIOSH. 2003. Work-Related Lung Disease lung disease Pulmonary disease Pulmonology Any condition causing or indicating impaired lung function Types of LD Obstructive lung disease–↓ in air flow caused by a narrowing or blockage of airways–eg, asthma, emphysema, chronic bronchitis; Surveillance Report 2002. Cincinnati, OH:National Institute of Occupational Safety and Health. Available: http://www.cdc.gov/niosh/ docs/2003-111/2003-111.html [accessed 13 June 2005]. Page SJ, Organiscak JA. 2000. Suggestion of a cause-and-effect relationship among coal rank, airborne dust, and incidence of workers' pneumoconiosis. AIHAJ AIHAJ American Industrial Hygiene Association Journal 61:785-787. Prather TA, Miller DD. 1992. Calcium carbonate depresses iron bioavailability in rats more than calcium sulfate or sodium carbonate. J Nutr 122:327-332. Ruckley VA, Gould SJ, Chapman JS, Davis JM, Douglas AN, Fernie JM, et al. 1984. Emphysema and dust exposure in a group of coal workers. Am Rev Respir Dis 129:528-532. Singer P, Stumm W. 1969. Acidic mine drainage: the rate-determining step. Science 167:1121-1123. Smith KR, Aust AE. 1997. Mobilization of iron from urban particulates leads to generation of reactive oxygen species reactive oxygen species, n molecules and ions of oxygen that have an unpaired electron, thus rendering them extremely reactive. Many cellular structures are susceptible to attack by ROS contributing to cancer, heart disease, and cerebrovascular disease. in vitro and induction of ferritin synthesis in human lung epithelial cells. Chem Res Toxico 110:828-834. Smith KR, Veranth JM, Hu AA, Lighty Light´y a. 1. Illuminated. JS, Aust AE. 2000. Interleukin-8 levels in human lung epithelial cells are increased in response to coal fly ash and vary with the bioavailability of iron, as a function of particle size and source of coal. Chern Res Toxicol 13:118-125. Soutar CA, Hurley JF, Miller BG, Cowie HA, Buchanan D. 2004. Dust concentrations and respiratory risks in coalminers: key risk estimates from the British Pneumoconiosis Field Research. Occup Environ Med 81:477-481. Srivastava RK, Jozewicz W. 2001. Flue gas desulfurization Flue gas desulfurization (FGD) is the current state-of-the art technology used for removing sulfur dioxide (SO2) from the exhaust flue gases in power plants that burn coal or oil to produce steam for the steam turbines that drive their electricity generators. : the state of the art. J Air Waste Manag Assoc 51:1676-1888. Wienk KJ, Marx JJ, Lemmens AG, Brink E J, Van Der Meer Van der Meer is a Dutch surname that simply means the phrase 'from the lake' in English. Many years ago, descendants would have lived from a lake in the Netherlands which is how the name first originated. R, Beynen AC. 1996. Mechanism underlying the inhibitory effect of high calcium carbonate intake on iron bioavailability from ferrous sulphate in anaemic a·nae·mic adj. Variant of anemic. anaemic or US anemic Adjective 1. having anaemia 2. pale and sickly-looking 3. lacking vitality Adj. rats. Br J Nutr 75:109-120. Zhang Q, Dai J, Ali A, Chen L, Huang X. 2002. Roles of bioavailable iron and calcium in coal dust-induced oxidative stress: possible implications in coal workers' lung disease. Free Radic Res 36:285-294. Zhang Q, Huang X. 2002. Induction of ferritin and lipid peroxidation by coal samples with different prevalence of coal workers' pneumoconiosis: role of iron in the coals. Am J Ind Med 42:171-179. Address correspondence to X. Huang, Department of Environmental Medicine and NYU NYU New York University NYU New York Undercover (TV show) Cancer Institute, New York University New York University, mainly in New York City; coeducational; chartered 1831, opened 1832 as the Univ. of the City of New York, renamed 1896. It comprises 13 schools and colleges, maintaining 4 main centers (including the Medical Center) in the city, as well as the School of Medicine, 550 First Ave., PHL Room 802, New York, NY 10016 USA. Telephone: (212) 263-6650. Fax: (212) 263-6649. E-mail: xihuang@env.med.nyu.edu This project was supported by grant OH 03561 from the National Institute for Occupational Safety and Health National Institute for Occupational Safety and Health, n.pr an institute of the Centers for Disease Control and Prevention that is responsible for assuring safe and healthful working conditions and for developing standards of safety and health. and in part by National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. Center grant ES00260. The authors declare they have no competing financial interests. Received 18 October 2004; accepted 14 April 2005. Xi Huang, (1) Weihong Li, (1) Michael D. Attfield, (2) Arthur Nadas, (7) Krystyna Frenkel, (1) and Robert B. Finkelman (3) (1) Department of Environmental Medicine and NYU Cancer Institute, New York University School of Medicine, New York, New York, USA; (2) Division of Respiratory Diseases Studies, National Institute for Occupational Safety and Health, Centers for Disease Control and Prevention, Morgantown, West Virginia, USA; (3) U.S. Geological Survey, Reston, Virginia, USA
Table 1. CWP prevalence and mean levels ([+ or -] SD; mmol/100 g
dry coal) of physicochemical properties of coal samples from each
coal mine region.
No. of No. of
State mines samples CWP (%)
PA 3 9 45.35
OH 1 6 31.80
KY 4 13 29.00
WV 4 8 28.25
AL 1 13 16.70
UT 2 4 13.10
CO 9 41 4.60
State MR (C:H) Si[O.sub.2]
PA 1.28 [+ or -] 0.12 71.05 [+ or -] 46.22
OH 1.09 [+ or -] 0.07 84.66 [+ or -] 26.96
KY 1.20 [+ or -] 0.07 69.82 [+ or -] 24.06
WV 1.32 [+ or -] 0.13 49.53 [+ or -] 24.00
AL 1.26 [+ or -] 0.07 71.84 [+ or -] 49.59
UT 1.08 [+ or -] 0.07 40.82 [+ or -] 8.51
CO 1.04 [+ or -] 0.06 117.3 [+ or -] 82.53
State CaO [S.sub.py]
PA 3.97 [+ or -] 2.13 34.76 [+ or -] 21.88
OH 5.23 [+ or -] 7.17 37.08 [+ or -] 20.03
KY 5.69 [+ or -] 9.70 25.48 [+ or -] 30.53
WV 4.58 [+ or -] 3.17 17.89 [+ or -] 29.57
AL 2.88 [+ or -] 2.96 17.07 [+ or -] 19.74
UT 7.33 [+ or -] 5.27 7.97 [+ or -] 4.35
CO 4.61 [+ or -] 2.3 3.43 [+ or -] 3.08
State S[O.sub.4] [Fe.sub.2][O.sub.3]
PA 1.23 [+ or -] 1.06 12.48 [+ or -] 7.4
OH 1.37 [+ or -] 1.20 12.86 [+ or -] 8.8
KY 0.43 [+ or -] 0.6 9.78 [+ or -] 9.11
WV 0.21 [+ or -] 0.21 7.27 [+ or -] 8.22
AL 0.11 [+ or -] 0.99 8.85 [+ or -] 5.86
UT 0.16 [+ or -] 0.06 2.69 [+ or -] 2.61
CO 0.21 [+ or -] 0.14 3.68 [+ or -] 1.86
State As Ni
PA 0.33 [+ or -] 0.4 0.26 [+ or -] 0.17
OH 0.17 [+ or -] 0.13 0.14 [+ or -] 0.19
KY 0.15 [+ or -] 0.22 0.22 [+ or -] 0.11
WV 0.22 [+ or -] 0.25 0.13 [+ or -] 0.05
AL 0.40 [+ or -] 0.29 0.17 [+ or -] 0.13
UT 0.01 [+ or -] 0.00 0.03 [+ or -] 0.00
CO 0.03 [+ or -] 0.05 0.07 [+ or -] 0.06
MR, molar ratio.
Table 2. Average levels (mmol/100 g dry coal) of total
[H.sub.2]S[O.sub.4] (1/2 [S.sub.py] + S[O.sub.4]), available amount of
acid (1/2 [S.sub.py] + S[O.sub.4] - CaO), total iron, and predicted
BAI. (a)
State No.of mines CWP (%) 1/2 [S.sub.py] + S[O.sub.4]
PA 9 45.35 18.61
OH 6 31.80 19.91
KY 13 29.00 13.17
WV 8 28.25 9.15
AL 13 16.70 9.65
UT 4 13.10 4.14
CO 41 4.60 1.92
1/2 [S.sub.py] +
State S[O.sub.4]-CaO (b,c) [Fe.sub.2][O.sub.3] BAI (d)
PA 14.63 12.48 11.82
OH 14.69 12.86 9.07
KY 7.49 9.78 6.25
WV 4.57 7.27 4.77
AL 6.77 8.85 5.29
UT -3.19 2.69 1.09
CO -2.69 3.68 0.15
(a) Levels of [S.sub.py], S[O.sub.4], CaO, and [Fe.sub.2][O.sub.3]
were obtained from the USGS database for each coal mine
(Bragg et al. 1998).
(b) CaO was presented as percentage of high-temperature ashes in the
USGS database and was converted to percentage of dry coal based on
the ash yield. Because 1 mol CaC[O.sub.3] produces 1 mol CaO in the
ashes, the molar amount of CaO per 100 g coal was used as a measure
of CaC[O.sub.3] levels in the coals. (c) Values in the individual
coal samples were calculated first and then averaged for the coal
mine region for each of physicochemical parameters listed. (d) BAI
was calculated as follows: if the difference in [1/2 [S.sub.py] +
S[O.sub.4] - CaO] is [less than or equal to] 0 for the individual
coal mine, the BAI is given as 0. If the difference in [1/2
[S.sub.py] + S[O.sub.4]-CaO] is > 0, a lesser value between
[1/2 [S.sub.py] + S[O.sub.4]-CaO] or total iron ([Fe.sub.2][O.sub.3])
is given for BAI (see text for details).
Table 3. Correlation among average levels of various parameters with
CWP prevalence.
C/H Si[O.sub.2] CaO [S.sub.py]
r-Value 0.59 0.28 -0.18 0.91
Lower 95% CI -0.26 -0.55 -0.78 0.35
Upper 95% CI 0.91 0.82 0.60 0.99
p-Value 0.16 0.54 0.69 0.0048
1/2 [S.sub.py] +
S[O.sub.4.sup.2-] S[O.sub.4.sup.2-]
r-Value 0.58 0.90
Lower 95% CI -0.26 0.40
Upper 95% CI 0.90 0.99
p-Value 0.17 0.006
1/2 [S.sub.py] +
S[O.sub.4.sup.2-] [Fe.sub.2][O.sub.3] BAI
r-Value 0.87 0.85 0.94
Lower 95% CI 0.25 0.20 0.66
Upper 95% CI 0.98 0.97 0.999
p-Value 0.01 0.016 0.0015
|
|
Printer friendly
Cite/link
Email
Feedback
Reader Opinion