Silicosis and Coal Workers' Pneumoconiosis Vincent Castranova and Val Vallyathan Pathology and Physiology Research Branch, Health Effects Laboratory Division, National Institute for Occupational Safety and Health, Morgantown, West Virginia, USA Exposure to coal mine dust and/or crystalline silica results in pneumoconiosis with initiation and progression of pulmonary fibrosis. This review presents characteristics of simple and complicated coal workers' pneumoconiosis (CWP) as well as pathologic indices of acute and chronic silicosis by summarizing results of in vitro, animal, and human investigations. These results support four basic mechanisms in the etiology of CWP and silicosis: a) direct cytotoxicity of coal dust or silica, resulting in lung cell damage, release of lipases and proteases, and eventual lung scarring; b) activation of oxidant production by pulmonary phagocytes, which overwhelms the antioxidant defenses and leads to lipid peroxidation, protein nitrosation, cell injury, and lung scarring; c) activation of mediator release from alveolar macrophages and epithelial cells, which leads to recruitment of polymorphonuclear leukocytes and macrophages, resulting in the production of proinflammatory cytokines and reactive species and in further lung injury and scarring; o) secretion of growth factors from alveolar macrophages and epithelial cells, stimulating fibroblast proliferation and eventual scarring. Results of in vitro and animal studies provide a basis for proposing these mechanisms for the initiation and progression of pneumoconiosis. Data obtained from exposed workers lend support to these mechanisms. Key words: black lung disease, coal mine dust, crystalline silica, cytokines, lung disease, occupational diseases, occupational exposures, pulmonary fibrosis, reactive oxygen species. - Environ Health Perspect 1 08(suppl 4):675-684 (2000). http.//ehpnetl.niehs.nih.gov/docs/2000/suppl-4/675-684castranova/abstract.html Silicosis and coal workers' pneumoconiosis (CWP) have long been recognized as signifi- cant occupational lung diseases. Silicosis and CWP continue to occur in several industrial workplaces even though these diseases are pre- ventable by environmental dust control. Although significant insights have been gained into mechanisms involved in the initiation and progression of silicosis and CWP, it is dif- ficult to conclude that these accomplishments have totally solved the problem of these occu- pational diseases. The knowledge acquired through research has been most valuable in determining the cause and pathogenesis of these occupational lung diseases. In industrial- ized countries, exposure-response information and the relationship among pathologic, radio- logic, and physiologic abnormalities of these diseases have led to the recommendation and implementation of exposure limits. However, additional innovative research strategies are vital to identify susceptible individuals, diag- nose these pneumoconioses in the early stages of development, and develop treatment strate- gies. In addition, research is needed to identify biologic mechanisms involved in unique occu- pational settings, for example, sandblasting, rock drilling, or exposure to mixed dusts, where risk of disease is unusually high. The literature concerning symptoms, clin- ical manifestations, and mechanisms for initi- ation and progression of silica-induced lung diseases and CWP is extensive. By intent, this review is meant to be brief and somewhat selective. Readers are directed to other sources if more detailed information is desired (1-12). This review is an overview of expo- sures, toxicologic and pathologic responses, and possible mechanisms involved in silicosis and CWP. Silica Exposures Silicosis is caused by inhalation of crystalline silica, mostly in occupational settings. It is most common among workers in underde- veloped countries. However, silicosis occurs frequently even in developed countries, par- ticularly in certain occupations such as mining, sandblasting, surface drilling, stone cutting, construction, pottery making, silica flour mill operations, and other occupations in which silica dust exposures occur (1-3). In addition, environmental exposure to crys- talline silica is common because of its abun- dance in soil. Silica can become airborne in arid, windy conditions or during agricultural, urban, and construction activities. Indeed, lung fibrosis and pulmonary changes associ- ated with environmental silica and mixed dust exposures have been observed in the lungs of farm animals and humans (13). In 1983 the National Institute for Occupational Safety and Health (NIOSH) estimated that approximately 2.3 million workers at 238,000 work sites may be exposed to silica dust (14). NIOSH estimates that as many as 59,000 workers may be at risk of developing some degree of silicosis, with 250 deaths/year being attributed to silica exposure (15). Approximately 1,500 cases of silicosis are diagnosed annually in the United States (16). NIOSH also reported that between 1968 and 1990 there were 13,744 deaths with mention of silicosis in the United States (16). However, in recent years, the annual number of deaths has decreased from 1,157 in 1968 to 301 in 1988 (16). Currently, several standards exist for the limitation of airborne levels of respirable crys- talline silica. The Occupational Safety and Health Administration permissible exposure limit (PEL) is 100 pg/m3 for an 8-hr work exposure. The NIOSH recommended expo- sure limit (REL) is 50 pg/m3 for up to 10 hr/day for a 40-hr work week. The American Conference of Governmental Industrial Hygienists threshold limit value is 100 pg/m3. In occupations such as rock drilling and sandblasting, measured respirable crys- talline silica levels often far exceed such stan- dards. It is likely that the majority of overt exposures occur in small, unregulated indus- trial settings or in high-hazard occupations such as sandblasting, drilling, tunneling, silica flour mill operations, and stone grinding. Little exposure-response information is avail- able concerning mixed exposures such as sil- ica and metal dust generated during abrasive blasting operations. Therefore, it is uncertain if such occupational exposures require unique exposure limits. Physical and Chemical Properties of Silica Silicons make up almost 28% of the earth's crust and are found in combination with many other minerals and metals. Silica can exist in either a crystalline or amorphous form. The crystalline types of silica (SiO2) include five polymorphs, i.e., quartz, tridymite, cristobalite, coesite, and stishovite (2,8). All these polymorphs are fibrogenic and biologically toxic. In most occupational expo- sures, quartz is the major type of silica involved. Amorphous silica and silicates are relatively less fibrogenic than crystalline silica (8). In the case of a-quartz, as well as the other crystalline polymorphs with the excep- tion of stishovite, the silicon dioxide (SiO2) molecules are arranged as a tetrahedral crystal This article is part of the monograph on Environmental and Occupational Lung Diseases. Address correspondence to V. Castranova, PPRB/HELD/NIOSH, 1095 Willowdale Rd., MS201 5, Morgantown, WV 26505 USA. Telephone: (304) 285- 6056. Fax: (304) 285-5938. E-mail: vicl@cdc.gov Received 3 August 1999; accepted 6 October 1999. Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 675 CASTRANOVA AND VALLYATHAN (8). In the presence of water, the surface of silica becomes hydrated to form silanol groups (-SiOH). It is believed that the high reactivity of crystalline silica to biologic mem- branes is due to the unique properties of these surface silanol groups. The first theory is that -SiOH groups are hydrogen donors, whereas most biologic macromolecules contain lone- pair electrons on oxygen or nitrogen that serve as hydrogen acceptors. The formation of hydrogen bonds would result in strong interaction between silica and biologic mem- branes, resulting in possible damage. A sec- ond theory is that the surface of silica is negatively charged. At pH 7.0, 1 in 30 -SiOH groups would be negatively charged (-SiO-). Negatively charged silica particles would react strongly with scavenger receptors on alveolar macrophages and would activate the generation of reactive oxygen species (ROS) and inflammatory cytokines (9,10). A third theory is that deavage of the silica crys- tal, as would occur in silica flour milling, rock drilling, and sandblasting, results in the gen- eration of Si and SiO' radicals on the frac- ture planes, which can induce oxidant damage (9,17,18). Stishovite is another poly- morph of pure crystalline silica that is distin- guished by its octahedral structure. Structural differences among these polymorphs are con- sidered to be important in their biologic reac- tivity, i.e., > quartz > tridymite > cristobalite > coesite > stishovite. Human Pathologic Reactions to Crystalline Silica Exposure Exposure to crystalline silica can result in adverse pulmonary responses such as acute sili- cosis, accelerated siicosis, chronic siicosis, and conglomerate silicosis (1). In addition, silica exposure may also be associated with systemic and autoimmune diseases such as sderoderma, rheumatoid arthritis, systemic lupus erythe- matosis, nephropathy, and proliferative glomerulonephritis (1,12). Tuberculosis is a common complication of silicosis often seen in severe grades of the disease. A possible associa- tion between siicosis and lung cancer is being accepted on the basis of evidence for a role of silica exposure in increased lung tumor forma- tion in experimental animals and exposed human populations (19). Acute Silicosis Acute silicosis (silicolipoproteinosis) results from exposure to relatively high levels of silica (3,20). It has been reported in occupations such as sandblasting, surface drilling, tunnel- ing, silica flour milling, and ceramic making. Morphologically the disease is characterized by pulmonary edema, interstitial inflamma- tion, and the accumulation within the alveoli of proteinaceous fluid rich in surfactant (1, 12). The exudate in the alveoli is eosinophilic, with a fine granular appearance (Figure 1). Radiographically, chest X rays exhibit a ground-glass appearance with dif- fuse lesions in the middle and lower lobes. Patients often suffer from labored breathing, fatigue, cough, weight loss, decreased pul- monary function, and compromised gas exchange. They develop cyanosis and respira- tory failure, often complicated by mycobacte- rial infections. It has been proposed that acute silicosis occurs in workers exposed to freshly fractured silica dust and that surface Si' and SiO' radicals generated during frac- turing play an important role in the rapid onset of this disease (17,18). Accelerated Silicosis Accelerated silicosis is commonly associated with heavy exposure as might occur in silica flour mill operations, sandblasting, and other crushing operations (12,20). It is similar in many respects to acute silicosis, exhibiting an exudative alveolar lipoproteinosis associated with chronic inflammation. In addition, accelerated silicosis is associated with fibrotic granulomas containing collagen, reticulin, and a large number of silica particles. The granulomas consist of a large number of mononuclear cells, fibroblasts, and collagen fibers with a predisposition for circular orien- tation showing the characteristic of immature silicotic nodules (12). The alveolar septa are lined with hypertrophic and hyperplastic alveolar type II epithelial cells with increased numbers of lamellar bodies. As with acute sil- icosis, accelerated silicosis also is associated with an increased morbidity and mortality. Figure 1. Acute silicosis showing granular eosinophilic exudate in alveolar spaces and interstitial inflammatory infiltration. Chronic Silicosis Inhalation of crystalline silica over prolonged periods promotes the formation of the classic fibrotic nodules having a typical histologic appearance of concentric arrangements of col- lagen fibers with central hyalinized zones (Figure 2). Typical concentric silicotic lesions with the whorled fibers of collagen are charac- teristic of silicotic lesions produced in humans by inhalation of crystalline silica and are mor- phologically distinct from lesions produced by other inorganic occupational exposures (1,12). The nodules show variable degrees of calcifica- tion and necrosis. Dust-containing macro- phages, fibroblasts, and lymphocytes are often restricted to the periphery of the nodules. Microscopically, lesions of silicosis, which are sharply demarcated from the adjoining lung parenchyma, usually range in size from few millimeters to several centimeters in diameter. Nodules are often found predominantly in the upper zones of the lungs and in subpleural areas. In pure silicosis, nodules are free of pig- mentation, and polarizing microscopy reveals dull birefringent partides, primarily in the cen- ter of the nodules. Radiographically, rounded opacities are evident initially in the upper lobes of the lung. As chronic siicosis progresses, pul- monary function deficits evidenced by decreases in static lung volumes and gas exchange become obvious. Conglomerate Silicosis Conglomerate silicosis results from the coales- cence and agglomeration of several smaller Figure 2. Chronic silicotic nodule showing characteristic features of this lesion. The amorphous center is sur- rounded by concentrically organized hyalinized collagen fibers. A cellular mantle of inflammatory cells is present at periphery. Mason's trichrome staining. Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 676 SILICOSIS AND COAL WORKERS' PNEUMOCONIOSIS nodules. In addition to the enlargement of nodules, profusion of nodular lesions increases and results in progressive massive fibrosis (PMF). Cavitation and extensive destruction of the lung parenchyma, including bronchi- oles and blood vessels, are common with PMF. According to the Silicosis and Silicate Disease Committee, a PMF lesion is defined as a lesion greater than 2 cm in diameter in contrast to the 1-cm or larger radiographic size established by the International Labour Office (ILO) (1). Silicosis and Tuberculosis In the beginning of this century, tuberculosis reached epidemic proportions in workers with silicosis. The advent of drug therapy and dust control measures has considerably reduced the prevalence of silicotuberculosis. However, an increased risk for tuberculosis has recently been reported in Danish foundry workers with advanced silicosis (21). In addi- tion, tuberculosis is still in great excess in South African gold miners and slate workers in Wales (22-24). The depressant effect of crystalline silica on the ability of alveolar macrophages to kill the tuberculosis mycobacterium was confirmed in experimen- tal studies (25). It is believed that silicosis leads to a reduction in cell-mediated immu- nity with alterations in lymphocyte subsets and serum immunoglobulin levels (26). Microscopically, the silicotic nodules, con- comitant with tuberculosis alterations, will have laminations and epithelioid cells with a lymphocyte collar. A caseation in the center of the silicotic nodule is common. Rheumatoid Complications Rheumatoid pneumoconiosis is rare in silico- sis. It is characterized by rapidly developing large opacities in a size range of 1-5 cm located mostly in the periphery of the lungs, often with only mild silicosis. Rheumatoid silicotic complications are often seen in patients with rheumatoid disease or in patients with a rheumatoid positive factor. Macroscopically, the lesions appear to have dark and light laminating bands with central necrosis. Microscopically, a central zone of fibrinoid necrosis with silica is surrounded by palisading histiocytes, neutrophils, lympho- cytes, and fibroblasts. Small blood vessels in the peripheral zones show clusters of lympho- cytes and plasma cells. Vascular Diseases Chronic hypoxia is a common cause of death in severe acute silicosis. Chronic hypoxia can bring about pulmonary vascular spasms as a result of the pulmonary disease caused by severe involvement of lung parenchyma. Morphologic alteration of the vasculature is common as a result of dust accumulation and fibrosis in PMF. In such cases of severe con- glomerate silicosis or PMF, pulmonary hyper- tension and cor pulmonale are common features and may become a cause of death. Glomerulonepliritis Mild-to-moderate abnormalities in both renal function and structure have been observed in workers exposed to crystalline silica. Numerous case reports of severe glomerulo- nephritis with renal failure occurring in per- sons with acute silicosis have been described as "silicon nephropathy" (27,28). Immunologic abnormalities are often reported as common in these cases and a potential exists for immune-mediated renal injury. Direct injury to cells by the microcrystalline silica particles is suspected as a possible cause based on the demonstration of increased numbers of silica particles in kidneys of silicotic patients. The association of silica exposure with focal glomerular disease in several case reports is difficult to ignore. Bronchogenic Carcinoma Since the first proposed hypothesis by Goldsmith et al. in 1982 indicating a proba- ble link between exposure to silica and lung cancer, several epidemiologic and pathologic studies have either supported or dismissed such a notion (19,29,30). In 1987, an International Agency for Research on Cancer (IARC) working group reviewed all the avail- able evidence and concluded that there was insufficient evidence for the carcinogenicity of crystalline silica in humans (30). These conclusions about carcinogenicity of silica in humans were influenced by five major short- comings: inappropriate controls, other occu- pational carcinogens, misclassification of silicotics, detection bias for silicosis, and chance of sampling variability (19,30). However, a recent working group organized by IARC in 1997 concluded that there is now sufficient evidence for the carcinogenic- ity of silica in humans (31-33). Several studies among the many reviewed by the [ARC working group on the question of sil- ica exposure and cancer risk in humans were negative or equivocal, and carcinogenicity of silica was not detected in all industrial opera- tions. However, nine studies showed exces- sive risk for lung cancer (19,32). These included refractory brick workers, pottery workers, diatomaceous earth workers, foundry workers, granite workers, and mine workers (19,32). It appears that the carcino- genic property of crystalline silica may be dependent on its biologic activity, polymor- phic nature, or specific industrial processes such as heat treatment and mechanical grind- ing. The relationship between the ability of silica to generate ROS and carcinogenesis has recently been reviewed (34). Coal Mine Dust Exposures Coal is a fossil fuel mined throughout the world. The generation of coal mine dust dur- ing underground coal mining is the most sig- nificant source of coal dust exposure. There are two basic types of coal mining operations, surface mining and underground mining, pro- ducing distinctively different exposure vari- ables and disease entities. Underground coal miners are at greater risk of developing CWP than strip or surface miners because of the higher dust levels in the underground envi- ronment. In strip or surface mining, generated coal dust is diluted by outdoor air. However, rock-drilling operations associated with sur- face mining are associated with a greater risk of developing silicosis. Recent data indicate that approximately 200,000 workers are employed in the coal mining industry in the United States. The Mine Safety and Health Administration (MSHA) respirable coal mine dust PEL is 2 mg/m3, while NIOSH has recently lowered its REL to 1 mg/m3 (35). Although dust levels are below 2 mg/m3 in most coal mines, MSHA has noted occasions in which the PEL is exceeded. High dust lev- els occur more often with long-wall mining than with conventional mining. Physical and Chemical Properties of Coal Although coal is mainly carbon, coal mine dust contains hydrogen, oxygen, nitrogen, trace metals, inorganic minerals, and crys- talline silica. Trace metals can include boron, cadmium, copper, nickel, iron, antimony, lead, and zinc. Some of these trace elements can be cytotoxic and carcinogenic in experi- mental models. Common mineral and ele- mental contaminants are kaolin, mica, pyrite, titanium, calcite, sulfur, sodium, magnesium, and silica. The rank of coal increases from peat to lignite, sub-bituminous to bitumi- nous, and anthracite. As rank increases, the ratio of carbon to other chemicals and min- eral contaminants increases. In general, anthracite coal mining has been associated with higher rates of pneumoconiosis than that found in bituminous miners (36,37). Anthracite coal mine dust contains more sur- face free radicals than bituminous coal, which may explain its higher cytotoxicity and patho- genicity (38-40). In addition, anthracite has a higher crystalline silica content than bitumi- nous coal (41). However, experimental evi- dence suggests that silica particles from bituminous mines may be coated with clay, rendering them less active (41). Respirable coal mine dust has a relatively large surface area due to its small aerodynamic size and porous nature. Organic aromatic compounds present in the coal atmosphere, such as ben- zene, methylene, phenol, and phenanthrene, Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 677 CASTRANOVA AND VALLYATHAN can be adsorbed onto the surface of coal mine dust and may affect its biologic activity. Human Pathologic Reactions to Coal Mine Dust Inhalation of coal mine dust can lead to the development of several diseases including CWP, bronchitis, emphysema, Caplan syn- drome, and silicosis (42,43). Coal miners typ- ically develop one of two forms of disease patterns-simple CWP or complicated CWP. With chronic exposure, the milder form of CWP may become complicated CWP, with enlargement and profusion of lesions in the lung. Black lung is a legal term used to include CWP, bronchitis, emphysema, and silicosis when they are found in association with employment history in coal mines. Coal Workers' Pneumoconiosis The first case report on CWP was by Gregory (44) in 1831 in a British coal miner. Initially coal dust was considered innocuous, and CWP was thought to be a variant of silicosis due to similarities in chest radiographs. This hypothesis was disproved by Collins and Gilchrist (45). They studied the pathologic changes in the lungs of coal trimmers exposed to coal that was free of silica and showed that workers developed pneumoconiosis despite low silica exposure. Gough et al. (46) and Heppleston (47,48) confirmed these findings and showed that the histologic pulmonary lesions in coal trimmers were identical to those found in underground coal miners. CWP is now clinically and pathologically distinguished from silicosis. The spectrum of lung lesions in coal work- ers is wide, and CWP is categorized according to the severity of disease (42,43). Simple CWP is characterized by the formation of black coal dust macules centered around the respiratory bronchioles, mostly in the upper lobes of the lung. The macules range in size from 1 to 6 mm in diameter and are irregular in size. Microscopically, macules contain coal dust-laden macrophages with a fine network of reticulin and some collagen fibers (Figure 3). Focal emphysema is a characteristic feature associated with these macules (43). These small coal dust- or carbonaceous material- laden pulmonary lesions have not been associ- ated with pulmonary symptoms. Increased exposure to coal mine dust results in the development of nodular lesions that are firm on palpation in contrast to non- palpable macules. They are classified on the basis of size as micronodules (< 7 mm diame- ter) and macronodules, which range in diam- eter from 8 mm to 2 cm (42). They develop at the bifurcations of respiratory bronchioles and are commonly seen against a background of macules, mostly in the upper lungs. Nodules contain heavily coal dust-laden macrophages interlaced with collagen fibers oriented in a haphazard manner and may have round, irregular, or stellate borders (Figure 4). The fibrotic stroma is composed of mature and immature collagen and retic- ulin. With chronic exposure to coal mine dust, nodules may converge and coalesce to produce lesions measuring larger than 2 cm with a fibrous nature. At this stage, the disease is called complicated CWP or PMF. Progressive Massive Fibrosis Progressive massive fibrosis is a generic term common in many pneumoconioses, includ- ing silicosis and CWP. In complicated CWP or PMF, lung function is compromised due to extensive fibrosis and emphysema. Progression of simple CWP to the more aggressive form of PMF is thought to be asso- ciated with severe cumulative dust exposure, concentration of inorganic minerals and sil- ica, impaired clearance, infections, and E . . .. immunologic factors (49-53). There is a tendency for PMF to progress with or with- out further exposure (49). Progression from simple CWP to PMF has been related to radiographic severity of disease, to coal mine dust exposure level, and to total dust burden. PMF lesions have a predilection to occur in the upper lobes of the right lung. However, in advanced cases, lesions are bilateral. Microscopically, PMF lesions appear as coal dust-laden irregular or round, well-demar- cated fibrotic masses of collagen bundles and haphazardly laid hyalinized collagen fibers intertwined with reticulin (Figure 5). Lesions may also appear as amorphous collagenization or clusters of nodules. Necrosis is often associ- ated with central cavitation, and cholesterol crystals are usually present. Vascular degenera- tive changes associated with bronchial and pulmonary arteries and lymphatic vessels are common in the lesions. Rheumatoid Pneumoconiosis (Caplan Syndrome) In coal miners with circulating rheumatoid factor, rheumatoid pneumoconiosis (Caplan syndrome) can occur (54,55). It is reported to be more common in Europe, particularly in Welsh miners. There is no evidence that coal mining predisposes workers to rheumatoid arthritis; however, it is often associated with severe categories of CWP (56). Macroscopi- cally, the nodules are pale yellow and show variable layers of concentric dark bands. The central zone is eosinophilic, granular, and necrotic, with fragments of nuclear material, collagen, and elastin often associated with cavitation and calcification. Microscopically, the nodules are similar to rheumatoid nod- ules, circumscribed, and range in size from 0.5 to 5 cm in diameter. The periphery of the lesion is composed of concentrically arranged collagen with lymphocyte, plasma Figure 3. Typical coal macule in the walls of respiratory bronchioles, with focal emphysema surrounding the macule. Figure 4. Stellate-shape micronodules developing around respiratory bronchioles. Greater collagen and fewer coal dust particles are distinguishable compared to macules. Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 678 SILICOSIS AND COAL WORKERS' PNEUMOCONIOSIS cells, and macrophages containing coal dust. Palisading fibroblasts and plasma cells are a characteristic feature of these lesions; they are rare in tuberculosis and other infectious granulomata (43). Silicosis in Coal Workers Silicosis in coal miners is rarely an isolated form of pneumoconiosis and is usually found in conjunction with simple CWP. Micro- scopically, silicotic nodules.appear with the typical concentric laminations of mature col- lagen surrounding a hyalinized and partially necrotic or calcified center. The nodule is sur- rounded by a pigmented zone often contain- ing histiocytes in reticulin stroma (Figure 6). Nodules are found more frequently in the upper lung zones but are also found in sub- pleural and peribronchiolar locations. Polarized light microscopy may reveal numer- ous weekly birefringent particles within the nodules and highly birefringent particles in the peripheral mantle. With chronic exposure to silica, confluence and profusion of lesions may occur, resulting in the development of conglomerate silicosis or PMF. Prevalence of silicosis in coal miners can be reliably determined only in autopsy studies because of the inability of chest radiography to distinguish between silicosis and CWP. Furthermore, eggshell calcification indicative of silicosis in radiographs is often not associ- ated with parenchymal silicosis in autopsy studies. Pathologic evaluations of 4,115 autopsy cases from the National Coal Workers' Autopsy Study from 1972 to 1996 have found 23% of coal miners with pul- monary silicosis and 58% with lymph node silicosis (57). Certain job categories such as tunnel drilling, roof bolting, and transporta- tion are associated with increased risk for developing silicosis (58). Relationship between Radiographic Category and Morphology of CWP Radiographically, simple CWP is classified according to the number, size, and shape of small opacities, which are most prevalent in the upper zones of both lungs. Multiple small rounded opacities on the chest radiographs are classified and categorized based on size (i.e., p, q, or r), shape (i.e., s, t, u), and profusion (i.e., 0, 1, 2, or 3) using standard reference films developed by the ILO (59). In simple CWP, radiographic opacities range in size from 0.001 to 1.0 cm, and in complicated CWP they are greater than 1.0 cm in diameter. Complicated CWP with opacities greater than 1.0 cm are defined in terms of their dimen- sion as A (< 50 mm), B (50 mm plus but not greater than right upper lung lobe), and C (exceeding the size of right upper zone). In general, there is good correlation between pathologic grading of disease severity and X- ray category; large opacities showed a better correlation with pathologic PMF (59). However, moderate-to-severe pathologic abnormality has to be present before abnor- mality can be detected radiographically with certainty. In cases with a radiographic profu- sion of 0/0, moderate numbers of macules and miconodules were present in pathologic evalu- ation (59). PMF may be confused in chest radiography with carcinoma, tuberculosis, or bacterial infectious lesions (59). Respiratory Symptoms of CWP Coal miners with milder forms of simple CWP usually have no symptoms. Nevertheless, in a small proportion of coal miners' abnormal pulmonary function tests, airflow obstruction and changes in diffusing capacity were observed with macules (pea-size small opaci- ties) (60). A 9-year follow-up study of coal miners with simple CWP (small rounded opacities) showed only a small fall in gas exchange (61). Such a small drop in gas exchange would not be expected to compro- mise arterial oxygen content even during mild exercise (62). It was, however, shown that lung mechanics are decreased in simple CWP, leading to an increase in residual vol- ume (63). Focal emphysema associated with coal macules is thought to be involved in col- lapse of small airways. In addition, a condi- tion known as industrial bronchitis is reported in coal miners with and without radiographic evidence of CWP (64). In complicated CWP, premature death is associated with pulmonary disability. Higher grades of PMF are associated with severe air- way obstruction, restrictive defects, abnor- malities in ventilation and perfusion, reduced diffusing capacity, and low arterial oxygen pressure (65). These progressive changes eventually lead to pulmonary hypertension and cor pulmonale (65). Lung Cancer in Coal Miners Lung cancer in coal miners occurs less frequently than in the general population after adjustment for age and smoking (66,67). Epidemiologic studies of British and U.S. coal miners reported a lower risk of lung cancer for miners compared to that in non- miners, and there was no apparent influence of mining tenure on the prevalence of lung tumors. There were also no changes in the histopathology of lung cancer cell types in coal miners, a point of view critically evalu- ated to assess the relationship of smoking (68). The tumors were mostly squamous cell (30%), adenocarcinoma (27%), and small cell (26%), again showing no influence of mining tenure on the frequency of these cell types. From these histopathologic studies, it is Figure 5. Progressive massive fibrosis lesion showing cavitation and distortion of the bronchiole and blood vessels. Necrosis in the cavity contains coal dust and dust- containing macrophages. Figure 6. Silicotic lesion in a coal miner's lung showing characteristic features of sili- cotic nodule, such as an amorphous center with concentrically arranged collagen fibers. Note the nodule is surrounded by coal dust. Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 679 CASTRANOVA AND VALLYATHAN evident that there are no apparent cellular differences in lung cancer of coal miners who smoke and the cigarette-smoking general population (68). In contrast to lung cancer, epidemiologic studies have revealed a higher-than-normal incidence of mortality from gastric cancer in coal miners compared to that in nonminers (69-71). A significant relationship between cumulative dust exposure and increased mor- tality from cancers of the digestive system was also evident from these studies. It has been suggested that nitrosation of ingested coal dust in the acidic gastric environment could result in the production of carcinogenic products, which may lead to the higher incidence of gas- tric cancer in coal miners (72). In support of this hypothesis, it was shown that upon nitro- sation of coal dust extracts they become muta- genic and are able to induce neoplastic transformation of mammalian cells (72,73). Mechanisms of Silica and Coal Pathogenicity Interstitial lung disease caused by exposure to silica and/or coal dust is the consequence of damage to lung cells and the resultant lung scarring associated with activation of the fibrotic process. The following mechanisms have been proposed to characterize this cycle of damage and scarring (9,10): * Direct cytotoxicity: Chemical features of silica or coal dust result in reaction with lung cells, leading to peroxidation of membrane lipids and damage to cell membranes. Damaged cells may release intracellular enzymes, which would cause further tissue damage, leading to scarring or destruction of alveolar septa. * Activation of oxidant generation by alveo- lar macrophages: Silica or coal dust stimu- lates the generation of ROS from alveolar macrophages, which overwhelms antioxi- dant defenses of the lung and causes lipid peroxidation and cell damage. Such dam- age may lead to scarring or destruction of alveolar septa. * Stimulation of the secretion of inflamma- tory cytokines and chemokines from alveolar macrophages and/or alveolar epithelial cells: These inflammatory medi- ators act as chemoattractants to recruit polymorphonuclear leukocytes (PMNs) and macrophages from pulmonary capil- laries to the air spaces. These cytokines also activate pulmonary phagocytic gener- ation of oxidant species, leading to tissue damage and scarring. * Stimulation of secretion of fibrogenic fac- tors from alveolar macrophages and/or alveolar epithelial cells: Release of fibro- genic factors results in induction of fibro- blast proliferation and/or the stimulation of collagen synthesis, leading to fibrosis. Direct Cytotoxicity The ability of silica or coal dust to cause lipid peroxidation and induce damage to cells or lung tissue is summarized in Table 1. In vitro and in vivo damage resulting from silica expo- sure has generally been reported to be more severe than with coal dust. Christian and Nelson (78) have correlated the cytotoxicity of coal dust with the nickel content of the mine dust samples. Samples from Pennsylvania coal mines had higher nickel content and exhibited greater cytotoxi- city than samples from Utah coal mines. This cytotoxicity was related to the higher rates of CWP in Pennsylvania mines than that reported in Utah. Dalal et al. (39) have found radicals on the fracture surfaces of freshly ground anthracite coal and noted that hemolytic activity of this coal dust decreased as these surface radicals decayed. Nash et al. (87) have suggested that SiOH groups on the surface of crystalline silica are capable of forming hydrogen bonds with membrane components, resulting in mem- brane injury and leakage. Polyvinylpyridine- N-oxide is thought to detoxify silica by acting as a proton acceptor and shielding the SiOH groups on quartz. Nolan et al. (88) have pro- posed that the negative surface charge of the SiO- groups is critical to cytotoxicity. It is possible that this negative charge allows silica to interact with scavenger receptors on alveo- lar macrophages (80,89). Indeed, neutraliza- tion of the surface of quartz with aluminum salts markedly reduces cytotoxicity (81). The grinding of silica results in the gener- ation of Si and SiO radicals on the fracture planes (17,90). Upon contact of these surface radicals with aqueous solution, hydroxyl radi- cals are generated (1?). There appears to be a direct relationship between the ability of silica particles to generate hydroxyl radicals and the potential to cause lipid peroxidation and cytotoxicity in vitro (17,91). A similar rela- tionship has been demonstrated in vivo as well (18,86). Surface iron plays an important role in augmenting silica-induced hydroxyl radical production and cytotoxicity both in vitro and in vivo (17,92). Activation of Oxidant Species Production by Alveolar Macrophages The production of reactive species (superoxide, hydrogen peroxide, nitric oxide) from alveolar macrophages has been associated with cell damage and disease (93). Indeed, a relation- ship has been reported between the level of oxidant production by pulmonary phagocytes and lung damage and severity of pneumoco- niosis (84,94). Silica- and/or coal dust-induced oxidant production from alveolar macrophages has been measured directly or by monitoring chemiluminescence in cellular, animal, and human exposure studies. The data are summa- rized in Table 2. As with direct cytotoxicity, silica appears to be a more potent stimulant of oxidant production than coal dust. Freshly fractured silica is a more potent stimulant of oxidant species production by alveolar macrophages than aged silica where surface radicals had decayed. This greater potency of fresh silica dust has been demon- strated after both in vitro and inhalation expo- sures of rat alveolar macrophages (86,99). Similarly, extremely high levels of chemilumi- nescence have been reported from a rock driller who was exposed to fresh silica and was diagnosed with acute siicosis (97). Stimulation of Inflammatory Cytokine Release As discussed above, silica and, to a lesser extent, coal dust can stimulate oxidant gener- ation. Evidence indicates that oxidant stress can activate the nuclear transcription factor NF-icB (100). Data indicate that silica can simulate NF-icB binding to DNA (101). Such binding to various gene promoters can result in mRNA production for a variety of inflammatory cytokines. Recent evidence indicates that silica-induced activation of another transcription factor, activation pro- tein-1, also may play an important role in the regulation of inflammatory cytokines (102). Table 1. Direct cytotoxicity of silica or coal mine dust. Toxic reaction Silica Coal dust Reference In vitro studies Lipid peroxidation e- + (74,75) Hemolysis ++ + (74-76) LDH release from alveolar macrophages ++ + (76,77) Inhibition of mammalian cell growth NR + (78) Increased permeability of Tll monolayers ++ NR (79 Apoptosis ++ NR (80) In vivo studies Lipid peroxidation ++ NR (18) Lavage enzyme levels ++ (81,82) Lavage protein ++ + (83-85) Lavage red blood cells ++ NR (18,86) Lavage lactate dehydrogenase ++ NR (83,85) Abbreviations and symbols: -, no significant response; +, significant response; ++, greater response than +; NR, response has not been reported. Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 680 SILICOSIS AND COAL WORKERS' PNEUMOCONIOSIS Excessive and prolonged inflammation of the lung has been associated with the develop- ment of pulmonary disease. In studies of silica exposure of rats, the recruitment of PMNs from the pulmonary capillaries to the alveolar airspaces is a hallmark of the initiation and progression of silica-induced lung disease (83,85,86,103). As with cytotoxic responses, the degree of pulmonary inflammation is related to the ability of the silica particles to generate radicals, i.e., freshly fractured silica exhibits more surface radicals and causes more PMN recruitment than aged silica (18,86). PMN recruitment has also been demonstrated as a hallmark of acute silicosis in humans (97). Exposure of animals to coal dust also results in inflammation characterized as an increase in the number of macrophages and PMNs in the alveolar space (82,104). In general the magni- tude of the inflammatory response to coal dust exposure is smaller than that to silica (84) and is less dominated by PMN recruitment (104). An increased number of alveolar macrophages have also been reported in coal miners, with the number of lavagable macrophages increas- ing with the severity of CWP (105). This recruitment of phagocytic cells into the alveolar spaces is in response to the particle- induced production of chemotactic cytokines and chemokines by alveolar macrophages and alveolar type II epithelial cells (106). A list of inflammatory cytokines and chemokines pro- duced in response to silica or coal dust exposure is given in Table 3. Leukotriene B4, platelet- activating factor (PAF), and interleukin (IL)-1 are chemotaxins for PMNs and in the case of IL-1 lymphocytes as well (6). Tumor necrosis factor alpha (TNF-a) may not be a direct chemoattractant factor; however, it is a potent stimulant of chemokines, such as macrophage inflammatory protein (MIP-1 or MIP-2) and cytokine-induced neutrophil chemoattractant (118). Indeed, the importance of TNF-a in the inflammatory reaction to silica has been emphasized by the fact that a) PMN recruit- ment exhibits a direct, linear relationship to TNF-a production in silica-exposed rats (119); and b) treatment of silica-exposed rats with anti-TNF-a dramatically attenuates PMN recruitment (118). Once PMNs are recruited into the alveo- lar spaces, several inflammatory cytokines act Table 2. Silica or coal dust-induced activation of oxidant release from alveolar macrophages. Response Silica Coal dust Reference In vitro studies Superoxide anion ++ NR (95) Hydrogen peroxide ++ NR (95) Chemiluminescence ++ NR (95) In vivo animal studies Hydrogen peroxide ++ NR (95) Chemiluminescence ++ + (82,86,95) Nitric oxide ++ + (84,86,96) Human studies-patients with silicosis or CWP Superoxide anion ++ + (94,98) Hydrogen peroxide ++ NR (98) Chemiluminescence ++ + (96,97) Nitric oxide + + (96) Abbreviations and symbols: +, significant response; ++, greater response than +; NR, response has not been reported. Table 3. Silica or coal dust-induced stimulation of cytokine and chemokine secretion from lung cells. Response Silica Coal dust Reference In vitro studies Platelet-activating factor ++ + (107) Leukotriene B4 ++ + (105) Prostaglandin E2 NR + (109) Thromboxane A2 NR + (109) TNF-ca ++ + (108,110) IIL-1 ++ + (111( IL-6 NR + (11a) In vivo animal studies Leukotriene B4 + + (112,113) Prostaglandin E2 + NR (112) Thromboxane A2 NR + (113) TNF-a ++ NR (114) IL-1 + NR (114) Macrophage inflammatory protein ++ NR (106) Human studies-patients with silicosis or CWP TNF-a NR + (115) IL-1 NR + (115) Monocyte chemoattractant peptide-1 NR + (115) IL-6 NR + (117 Abbreviations and symbols: +, significant response; ++, greater response than +; NR, response has not been reported. to stimulate oxidant production by these phagocytes. This would increase the oxidant burden in the lung, overwhelm antioxidant defenses, and cause lung injury and scarring. Indeed, activation of ROS production by PMNs has been demonstrated in response to PAF, TNF-a, and IL-1 (107,119). Stimulation of Fibrogenic Factor Release A number of cytokines produced by alveolar macrophages have regulatory effects on fibroblast growth and/or collagen synthesis. When the balance between fibrotic and anti- fibrotic mediators shifts, pulmonary fibrosis can develop. IL-1 (120), TNF-a (121), platelet-derived growth factor (PDGF) (122), fibronectin (123), alveolar macrophage- derived growth factor (123), and type 1 insulinlike growth factor (124) have been reported to increase fibroblast proliferation. PDGF and fibronectin are competence fac- tors, whereas alveolar macrophage-derived growth factor is a progression factor for pro- liferation of fibroblasts. IL-1 has also been described as a direct stimulant of collagen production (125). TNF-ct is not only a direct proliferative agent for fibroblasts but also stimulates the secretion of PDGF in vitro (126). A critical role of TNF-a in pulmonary fibrosis is demonstrated by the fact that anti- TNF-ax significantly decreased silica-induced pulmonary fibrosis in a mouse model (127). In contrast, IL-6 exhibits antifibrotic activ- ity (128). Prostaglandin E2 and transforming growth factor beta (TGF-P) exhibit a depres- sive effect on cell growth (122,124). However, under certain conditions, TGF-P can stimu- late collagen synthesis in vitro (129). The effects of silica or coal dust exposure on alveolar macrophage production of cytokines that regulate fibrogenesis are listed in Table 4. Although exposure has been reported to stimulate both fibrogenic and antifibrogenic factors, it appears the balance shifts toward fibrotic stimuli. For example, TNF-a, type 1 insulinlike growth factor, and PDGF all increase as simple CWP progresses to PMF. Data Gaps and Unresolved Issues in Silicosis * Controversy over the relationship between crystalline silica exposure and the development of lung cancer still exists. Further evidence from both experimental animal studies and human investigations is desirable. * Why does silica induce lung tumors in rat models but not in mice or hamsters? What is the mechanistic reason for this difference? * In rats, silica-induced lung tumors have been associated with a particle overload. Is silica overload a prerequisite for the neo- plastic response in humans? Environmental Health Perspectives * Vol 108, Supplement 4 * August 2000 681 CASTRANOVA AND VALLYATHAN Table 4. Silica or coal dust-induced stimulation of fibrogenic factor secretion from lung cells Response Silica Coal dust Reference In vitro studies TNF- a ++ + (108,110) IL-1 ++ + (111) Prostaglandin E2 NR + (l09) [L-6 NR + (110) In vivo animal studies TNF-a ++ NR (114) IL-1 + NR (114) Fibronectin + NR (114) TGF-,B + NR (130) Prostaglandin E2 + NR 112) Human studies-patients with silicosis or CWP TNF-a NR + (115) IL-1 NR + (115) Fibronectin + + (98) Alveolar macrophage-derived growth factor + + (98) Platelet-derived growth factor NR + (124) Type I insulinlike growth factor NR + (124) TGF-P NR + ( 124) [l-6 NR + (117) Abbreviations and symbols: +, significant response; ++, greater response than +; NR, response has not been reported. * Lung carcinomas in silica-exposed rats tend to be mostly in peripheral airways and adenocarcinomas/bronchoalveolar carcinomas are the frequent cell types. Is there a predilection in humans for similar tumors? * Dose-response relationships between tumor incidence and exposure to crys- talline silica is required in both animal models and human studies. * Is silicosis in the lymph nodes associated with excess lung cancer? Does this impede the clearance of other carcinogens from the lung and provide an increased resi- dence time? If so, what evidence is avail- able to support DNA damage or increased frequency of mutations? * Is pulmonary fibrosis a prerequisite for silica-induced lung cancer in humans? * Is an oxidant burden (particle derived and/or inflammation derived) an intrinsic mechanism involved in triggering silica- induced tumors? * Is crystalline silica a direct-acting carcino- gen or cocarcinogen? Is it an initiator or promoter? * Why do different strains of mice exhibit different susceptibilities to silica-induced fibrosis? What are the mechanistic differ- ences involved? * Since freshly fractured silica is more cyto- toxic and inflammatory than aged silica, does this necessitate a lower exposure standard in occupations that generate freshly fractured silica dust? How much lower should the standard be? * What is the toxicity of abrasive blasting substitutes in relationship to silica? Do safe substitutes exist? * Can biomarkers be developed to identify adverse reactions to silica before disease becomes irreversible? * Can silicosis be treated or its progression inhibited? 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