Use of an in vivo test system to investigate the acute and sub-acute responses of the rat lung to mineral dusts

Final Report on the Safety Assessment of Aluminum Silicate, Calcium Silicate, Magnesium Aluminum Silicate, Magnesium Silicate, Magnesium Trisilicate, Sodium Magnesium Silicate, Zirconium Silicate, Attapulgite, Bentonite, Fuller's Earth, Hectorite, Kaolin, Lithium Magnesium Silicate, Lithium Magnesium Sodium Silicate, Montmorillonite, Pyrophyllite, and Zeolite

This report reviews the safety of Aluminum, Calcium, Lithium Magnesium, Lithium Magnesium Sodium, Magnesium Aluminum, Magnesium, Sodium Magnesium, and Zirconium Silicates, Magnesium Trisilicate, Attapulgite, Bentonite, Fuller's Earth, Hectorite, Kaolin, Montmorillonite, Pyrophyllite, and Zeolite as used in cosmetic formulations. The common aspect of all these claylike ingredients is that they contain silicon, oxygen, and one or more metals. Many silicates occur naturally and are mined; yet others are produced synthetically. Typical cosmetic uses of silicates include abrasive, opacifying agent, viscosity-increasing agent, anticaking agent, emulsion stabilizer, binder, and suspending agent. Clay silicates (silicates containing water in their structure) primarily function as adsorbents, opacifiers, and viscosity-increasing agents. Pyrophyllite is also used as a colorant. The International Agency for Research on Cancer has ruled Attapulgite fibers >5 μm as possibly carcinogenic to humans, but fibers <5 μm were not classified as to their carcino-genicity to humans. Likewise, Clinoptilolite, Phillipsite, Mordenite, Nonfibrous Japanese Zeolite, and synthetic Zeolites were not classified as to their carcinogenicity to humans. These ingredients are not significantly toxic in oral acute or short-term oral or parenteral toxicity studies in animals. Inhalation toxicity, however, is readily demonstrated in animals. Particle size, fibrogenicity, concentration, and mineral composition had the greatest effect on toxicity. Larger particle size and longer and wider fibers cause more adverse effects. Magnesium Aluminum Silicate was a weak primary skin irritant in rabbits and had no cumulative skin irritation in guinea pigs. No gross effects were reported in any of these studies. Sodium Magnesium Silicate had no primary skin irritation in rabbits and had no cumulative skin irritation in guinea pigs. Hectorite was nonirritating to the skin of rabbits in a Draize primary skin irritation study. Magnesium Aluminum Silicate and Sodium Magnesium Silicate caused minimal eye irritation in a Draize eye irritation test. Bentonite caused severe iritis after injection into the anterior chamber of the eyes of rabbits and when injected intralamellarly, widespread corneal infiltrates and retrocorneal membranes were recorded. In a primary eye irritation study in rabbits, Hectorite was moderately irritating without washing and practically nonirritating to the eye with a washout. Rats tolerated a single dose of Zeolite A without any adverse reaction in the eye. Calcium Silicate had no discernible effect on nidation or on maternal or fetal survival in rabbits. Magnesium Aluminum Silicate had neither a teratogenic nor adverse effects on the mouse fetus. Female rats receiving a 20% Kaolin diet exhibited maternal anemia but no significant reduction in birth weight of the pups was recorded. Type A Zeolite produced no adverse effects on the dam, embryo, or fetus in either rats or rabbits at any dose level. Clinoptilolite had no effect on female rat reproductive performance. These ingredients were not genotoxic in the Ames bacterial test system. In primary hepatocyte cultures, the addition of Attapulgite had no significant unscheduled DNA synthesis. Attapulgite did cause significant increases in unscheduled DNA synthesis in rat pleural mesothelial cells, but no significant increase in sister chromosome exchanges were seen. Zeolite particles (<10 μm) produced statistically significant increase in the percentage of aberrant metaphases in human peripheral blood lymphocytes and cells collected by peritoneal lavage from exposed mice. Topical application of Magnesium Aluminum Silicate to human skin daily for 1 week produced no adverse effects. Occupational exposure to mineral dusts has been studied extensively. Fibrosis and pneumoconiosis have been documented in workers involved in the mining and processing of Aluminum Silicate, Calcium Silicate, Zirconium Silicate, Fuller's Earth, Kaolin, Montmorillonite, Pyrophyllite, and Zeolite. The Cosmetic Ingredient Review (CIR) Expert Panel concluded that the extensive pulmonary damage in humans was the result of direct occupational inhalation of the dusts and noted that lesions seen in animals were affected by particle size, fiber length, and concentration. The Panel considers that most of the formulations are not respirable and of the preparations that are respirable, the concentration of the ingredient is very low. Even so, the Panel considered that any spray containing these solids should be formulated to minimize their inhalation. With this admonition to the cosmetics industry, the CIR Expert Panel concluded that these ingredients are safe as currently used in cosmetic formulations. The Panel did note that the cosmetic ingredient, Talc, is a hydrated magnesium silicate. Because it has a unique crystalline structure that differs from ingredients addressed in this safety assessment, Talc is not included in this report.

Distribution of glass fibers in the peritoneal cavity of the rat following administration by intraperitoneal injection

The distribution of glass fibers in the peritoneal cavity of the rat was investigated at 2, 24, and 48 h following intraperitoneal injection of 1 mg of material using a radioactive tracer technique. At each time point the peritoneal cavities of the rats killed were lavaged with 20 ml of physiological saline to recover fibers not yet attached to tissue surfaces. At 2 h, 35% of the administered fiber could be recovered by lavage, but at 48 h this was reduced to 2%. At 48 h, the amount of fiber associated with the abdominal organs and the abdominal wall was roughly in proportion to their surface areas. The weight of fiber associated with the various tissues was in the following order: gastrointestinal tract > liver > carcass (abdominal wall) > diaphragm > urogenital tract > spleen > kidneys. Differential counts on cells recovered by lavage were made both on cytocentrifuge slides and by flow cytometry. Compared with controls, the numbers of cells recovered from treated rats at 24 and 48 h were increased by a factor of about 2, due mainly to an influx of neutrophils into the peritoneal cavity. There was a marked reduction in the proportion of mast cells compared to controls.

Stimulation of rat alveolar macrophage fibronectin release in a cadmium chloride model of lung injury and fibrosis

Rats were exposed to saline or cadmium chloride (CdCl2) at 25, 100, or 400 micrograms/kg body weight by intratracheal instillation. At 3, 7, 14, and 28 days after exposure five animals/treatment were euthanized, the lungs were lavaged, and bronchoalveolar lavage fluid (BALF) was analyzed for lactate dehydrogenase (LDH), total protein, N-acetylglucosamindase (NAG), and cell number, type, and viability. Lung hydroxyproline concentration was characterized as a marker of lung collagen. Alveolar macrophages (AM) obtained in BALF were cultured and the release of fibronectin and TNF was determined. Lung tissue was examined microscopically at 28 and 90 days after exposure. Exposure to CdCl2 resulted in lung injury and inflammation demonstrated by increases in BALF LDH, total protein, NAG, and inflammatory cells. AM TNF release was not significantly changed by CdCl2 treatment. All doses of CdCl2 stimulated AM fibronectin secretion, a response which persisted throughout the 28-day postexposure period examined. Pulmonary fibrosis was demonstrated biochemically and/or histologically (trichrome staining tissue) at all CdCl2 dose levels. The association of CdCl2-induced AM fibronectin release with lung fibrosis confirms and extends previous observations relating AM-derived fibronectin to the development of interstitial lung disease and provides further evidence that the persistent increase in AM fibronectin release represents an early indicator of fibrosis.

Pulmonary response to inhaled silica or titanium dioxide

The pulmonary response to mineral dust inhalation was investigated by characterizing markers of lung injury and inflammation, macrophage activation, dust clearance, and histopathology. Rats were exposed (6 hr/day x 5 days) to air or 50 mg/m3 crystalline silica (SiO2) or titanium dioxide (TiO2). At 7, 14, 28, and 63 days after exposure, bronchoalveolar lavage fluid (BALF) was analyzed for lactate dehydrogenase (LDH), total protein, and N-acetylglucosaminidase, as well as cell number, type, and viability. Alveolar macrophages (AM) obtained in BALF were cultured with or without LPS and release of interleukin-1 (IL-1) and fibronectin was determined. Histopathology was conducted at 28 and 63 days. The exposure protocol resulted in 1.8-1.9 mg of mineral dust being deposited in the pulmonary region. Clearance of SiO2 was significantly less than TiO2. SiO2 increased BALF neutrophils (Days 14, 28, and 63), total protein (Days 28 and 63), and LDH and lymphocytes (Day 63). SiO2 increased AM-derived fibronectin release (Day 63) and LPS-induced IL-1 release (all time points), but not spontaneous release of IL-1. TiO2 did not change BALF biochemical or cellular parameters or AM secretory activity. Histopathology revealed minimal interstitial inflammation with SiO2 and no significant response in control or TiO2 rats. These results demonstrate the pulmonary response to inhaled SiO2 can be differentiated from the relatively innocuous TiO2 by changes in BALF markers of injury and inflammation further supporting the use of BALF analysis to make relative assessments of pulmonary toxicity. The stimulation of macrophage fibronectin release by the fibrogenic dust SiO2 and not TiO2 is consistent with a role for this glycoprotein in lung injury and repair. Last, the early and persistent effect of SiO2 on LPS-induced AM IL-1 release indicates this response may represent a sensitive early marker of dust-induced changes in the AM population.

Development of a short-term inhalation bioassay to assess pulmonary toxicity of inhaled particles: comparisons of pulmonary responses to carbonyl iron and silica

This paper describes a short-term inhalation bioassay for evaluating the lung toxicity of inhaled particulate materials. To validate the method, rats were exposed for 6 hr or 3 days to various concentrations of either aerosolized alpha-quartz silica or carbonyl iron particles. Cells and fluids from groups of sham- and dust-exposed animals were recovered by bronchoalveolar lavage (BAL). Alkaline phosphatase, lactate dehydrogenase (LDH), and protein values were measured in BAL fluids at several time points postexposure. Cells were identified, counted, and evaluated for viability. Pulmonary macrophages (PM) were cultured and studied for morphology, chemotaxis, and phagocytosis by scanning electron microscopy. The lungs of additional exposed animals were processed for histopathology and transmission electron microscopy. Brief exposures to silica elicited a sustained granulocytic inflammatory response (primarily neutrophils) with concomitant increases in alkaline phosphatase, LDH, and protein in the lavage fluids (p less than 0.05). In addition, PM functional capacity was depressed (p less than 0.05) and histopathologic lesions were observed within 1 month after exposure. In contrast, 6-hr or 3-day exposures to CI produced no cellular, cytotoxic, or alveolar/capillary membrane permeability changes at any time postexposure. PM function was either enhanced or unchanged from controls. These data demonstrate that short-term, high-dose inhalation exposures of silica produce effects similar to those previously observed using intratracheal instillation or chronic inhalation models, and lend support to this method as a reliable short-term bioassay for evaluating the pulmonary toxicity and mechanisms associated with exposures to new and untested materials.

The comparison of a fibrogenic and two nonfibrogenic dusts by bronchoalveolar lavage

Analysis of bronchoalveolar lavage fluid (BALF) appears to be a sensitive approach to characterizing an acute inflammatory response within the lung. More work, however, is needed to determine if analyses of BALF endpoints can predict chronic responses (i.e., fibrosis). The objective of the present study was to compare the dose and temporal pulmonary response of a known fibrogenic agent, silica, and two known nonfibrogenic agents, aluminum oxide and titanium dioxide. Animals were instilled with silica (0, 0.2, 1.0, or 5.0 mg/100 g body wt), titanium dioxide (1.0 or 5 mg/100 g body wt), aluminium oxide (1.0 or 5.0 mg/100 g body wt) or saline. Animals (n = 5/group) were terminated 1, 7, 14, 28, and 63 days following instillation, and the BALF was characterized by biochemical and cellular assays. Histopathological changes were determined at 60 days after exposure. The biochemical results demonstrated BALF levels of lactate dehydrogenase (LDH), beta-glucuronidase (BG), N-acetylglucosaminidase (NAG), and total protein (TP) increased in a dose-related fashion at the earlier time points for all test materials, with the magnitude of change being greatest for silica. The temporal response for these parameters was significantly different for the two classes of materials. With time, the response for the fibrogenic dust steadily increased, while the levels for the nonfibrogenic dusts decreased toward normal values during the 2-month study period. Of the cellular changes, total cell numbers, neutrophils, and lymphocyte numbers were the most sensitive markers of the pulmonary response. As shown with the biochemical parameters, the cellular response to silica increased with time while that of the nuisance dusts did not. It was also found that, similar to inhalation studies, high doses of a nuisance dust may result in toxicity/inflammation. This toxicity at high dose levels emphasizes the importance of choosing relevant doses when comparing potentially fibrogenic and nonfibrogenic dusts. In conclusion, the persistent and progressive changes seen in the biochemical (LDH, TP, BG, NAG) and cellular parameters (total cells, neutrophils and lymphocytes) following silica administration correlated with the fibrotic response which occurred after exposure to this material. The less dramatic and transient changes seen with aluminum oxide and titanium dioxide correlated with the inert nature of these nuisance dusts. The results of this study indicate evaluation of BALF may provide a means to predict the chronic pulmonary response to a material.

Interleukin 1 production and accessory cell function of rat alveolar macrophages exposed to mineral dust particles

Immunostimulatory effects of respirable mineral dust particles on alveolar macrophages (AM) and T lymphocytes were tested in vitro. When rat AM were incubated with fibrogenic silica and asbestos particles, a significant interleukin 1 (IL-1) activity was generated into the culture supernatants, whereas neither AM alone nor AM incubated with non-fibrogenic titanium dioxide (TiO2) particles, however, produced a detectable amount of IL-1. Interleukin 2 (IL-2) activity, as tested with IL-2-dependent CTLL-2 assays, was not detectable from all of these cultures. It was also revealed that concanavalin A-induced proliferation of T lymphocytes was enhanced in autologous AM and nylon wool-passed spleen cell co-cultures incubated only with fibrogenic particles, but not with non-fibrogenic particles. Higher IL-1 activity was detected only from co-cultures exposed to fibrogenic particles, whereas IL-2 activity was almost similar among these co-cultures. These results indicate the differences in immunostimulatory effects on pulmonary macrophages and T lymphocytes among a variety of mineral dust particles.

The combination of ozone and silica on the development of pulmonary fibrosis

The biologic interactions of potentially fibrogenic agents commonly occurring as environmental pollutants remain to be rigorously characterized. Two agents that produce pulmonary fibrosis were selected for this study. Separate groups of male Sprague-Dawley rats were intratracheally instilled with 0, 2, 12, and 50 mg silica and then either sham-exposed or exposed to 0.8 ppm ozone 6 h/d, 5 d/w, for 37 exposure days. Interaction was not detected between silica and ozone in the development of pulmonary fibrosis as determined by quantitative biochemical indices (hydroxyproline and lysyl oxidase) or by histopathologic examination of the lungs. Thus, environmentally relevant levels of ozone appear unlikely to affect the progression of a concurrent silicotic lesion.

Short term in vivo method for prediction of the fibrogenic effect of different mineral dusts

The effect of intratracheal introduction of different metal and mineral dusts and the change in activity of pulmonary acidic phosphatase have been studied as a function of time (72 h, 2 weeks, 1, 12, 20 months). The activity and localization of acid phosphatase were compared with the degree of pulmonary damage caused by dusts. The degree of fibrosis was determined on the basis of the composition of cells and fibres, according to Belt and King's classification. Due to the membrane-damaging effect of DQ 12 silica and mixed dusts (enargite and porphyry rock dusts) an increase in acid phosphatase activity of macrophages could be observed at the end of the first month. At the same time non-fibrogenic or only mild fibrogenic dusts (bentonite, corundum, scarnic rock dust) caused a decrease or disappearance of tissue acid phosphatase activity. It has been stated that there is a very close correlation between the change in pulmonary acidic phosphatase activity and the progression of pulmonary fibrosis due to exposure to mineral dusts. The above investigations have been most useful in predicting the subsequent effect of rock patterns, emphasizing at the same time the importance of in vivo long term experiments.