Asbestos inhalation induces reactive nitrogen species and nitrotyrosine formation in the lungs and pleura of the rat.

To determine whether asbestos inhalation induces the formation of reactive nitrogen species, three groups of rats were exposed intermittently over 2 wk to either filtered room air (sham-exposed) or to chrysotile or crocidolite asbestos fibers. The rats were killed at 1 or 6 wk after exposure. At 1 wk, significantly greater numbers of alveolar and pleural macrophages from asbestos-exposed rats than from sham-exposed rats demonstrated inducible nitric oxide synthase protein immunoreactivity. Alveolar macrophages from asbestos-exposed rats also generated significantly greater nitrite formation than did macrophages from sham-exposed rats. Strong immunoreactivity for nitrotyrosine, a marker of peroxynitrite formation, was evident in lungs from chrysotile- and crocidolite-exposed rats at 1 and 6 wk. Staining was most evident at alveolar duct bifurcations and within bronchiolar epithelium, alveolar macrophages, and the visceral and parietal pleural mesothelium. Lungs from sham-exposed rats demonstrated minimal immunoreactivity for nitrotyrosine. Significantly greater quantities of nitrotyrosine were detected by ELISA in lung extracts from asbestos-exposed rats than from sham-exposed rats. These findings suggest that asbestos inhalation can induce inducible nitric oxide synthase activation and peroxynitrite formation in vivo, and provide evidence of a possible alternative mechanism of asbestos-induced injury to that thought to be induced by Fenton reactions.

Pleural macrophage recruitment and activation in asbestos-induced pleural injury.

The pathogenesis of asbestos-induced pleural fibrosis is poorly understood. Moreover, there has been a long-standing controversy regarding the relative potential of different commercial types of asbestos to cause pleural disease. We postulated that inhaled asbestos fibers translocate to the pleural space where they stimulate the recruitment and activation of pleural macrophages. To test this hypothesis, and to determine whether there are differences between inhaled amphibole and serpentine asbestos, Fischer 344 rats were exposed by intermittent inhalation (6 hr/day for 5 days/week over 2 weeks) to either National Institute of Environmental Health Sciences (NIEHS) crocidolite (average concentration 7.55 mg/m3) or NIEHS chrysotile fibers (average concentration 8.51 mg/m3). Comparisons were made with sham-exposed rats. The rats were sacrificed at 1 and 6 weeks after the cessation of exposure. More pleural macrophages were recovered at 1 and 6 weeks after crocidolite and chrysotile exposure than after sham exposure. Small numbers of crocidolite fibers (approximately 1 per 4000 cells) were detected in the pleural cell pellet of one crocidolite-exposed rat by scanning electron microscopy. Pleural macrophage supernatants were assayed for production of nitric oxide (NO) (by the Griess reaction) and tumor necrosis factor alpha (TNF-alpha) (by an enzyme-linked immunosorbent assay method). Significantly greater amounts of NO as well as TNF-alpha were generated by pleural macrophages at 1 and 6 weeks after either crocidolite or chrysotile inhalation than after sham exposure. Conceivably, translocation of asbestos fibers to the pleural space may provide a stimulus for persistent pleural space inflammation, cytokine production, and the generation of toxic oxygen and nitrogen radicals. Enhanced cytokine secretion within the pleural space may in turn upregulate adhesion molecule expression and the synthesis of extracellular matrix constituents by pleural mesothelial cells. Thus, our findings may have significance for the development of asbestos-induced pleural injury.

Inhalation of acid coated carbon black particles impairs alveolar macrophage phagocytosis.

A flow-past nose-only inhalation system was used for the co-exposure of mice to carbon black aerosols (CBA) and sulfur dioxide (SO2) at varying relative humidities (RH). The conversion of SO2 to sulfate (SO4(-2)) on the CBA, at a fixed aerosol concentration, was dependent on RH and SO2 concentration. The effect of the aerosol-gas mixture on alveolar macrophage (AM) phagocytosis was assessed three days following exposure for 4 h. Exposure to 10 mg/m3 CBA alone at low RH (10%) and high RH (85%), to 10 ppm SO2 alone at both RH, and to the mixture at low RH had no effect on AM phagocytosis. In contrast, AM phagocytosis was significantly suppressed following co-exposure at 85% RH, the only circumstance in which significant chemisorption of the gas by the aerosol and oxidation to SO4(-2) occurred. The results suggest that fine carbon particles can be an effective vector for the delivery of toxic amounts of SO4(-2) to the periphery of the lung.

Silicosis in mice: effects of dose, time, and genetic strain.

Experimental silicosis allows study of the mechanisms of lung injury, inflammation, and fibrosis. Inbred mice are an attractive species in which to study these mechanisms because of recent progress in murine immunology, molecular biology, and genetics. We exposed mice to an aerosol of silica and examined the effects of exposure dose, the evolution of disease features over time, and the variation in responses among four inbred strains. In C3H/HeN mice incremental cumulative exposure doses of cristobalite silica caused increased initial lung dust burden 12 to 16 weeks post-exposure, progressively intense pathological responses, and increased total lung collagen (hydroxyproline). The histopathological changes and total lung collagen increased progressively over time after exposure. We compared the features of silicosis in four strains of inbred mice selected for common use or immunologic reactivity 16 weeks after aerosol inhalation exposure to crystalline cristobalite silica (70 mg/m3, 5 hours/day, 12 days). C3H/HeN mice demonstrated histopathological silicotic lesions and enlarged intrapulmonary lymphoid tissue, and increased lung wet weight, bronchoalveolar lavage (BAL) recovery of macrophages, lymphocytes, and neutrophils, and total lung collagen (hydroxyproline). BALB/c mice developed slight pulmonary lesions; MRL/MpJ mice demonstrated prominent pulmonary infiltrates with lymphocytes; New Zealand Black mice developed extensive alveolar proteinaceous deposits, inflammation, and fibrosis. Our findings demonstrate orderly dose-time-response relationships, and a substantial variation of responses among inbred strains of mice. This model should prove valuable for future experimental interventions into the mechanisms of silicosis.

Persistent overexpression of interleukin-1beta and tumor necrosis factor-alpha in murine silicosis.

The cytokines interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNFalpha), derived from macrophages and other cells, may promote mononuclear cell inflammation and fibrosis in pulmonary silicosis. C3H/HeN mice were exposed to control air or to an aerosol of 70 mg/m3 cristobalite silica for 5 h/d for 12 days and examined at 2 and 16 weeks after exposure. This exposure resulted in murine silicosis, as manifested by focal mononuclear cell accumulations, diffuse interstitial fibrosis, lymphoid tissue enlargement, recruitment of inflammatory cells into BAL fluid, and increased total lung collagen. Semiquantitative reverse transcription-polymerase chain reaction (RT-PCR) with designed primers and membrane hybridization with biotinylated cDNA probes were used to assess the abundance of IL-1beta and TNFalpha mRNA. In situ hybridization with digoxigenin-labeled cDNA probes was used to localize gene expression. Persistent overexpression of both IL-1beta and TNFalpha were found at 2 and 16 weeks in the lungs of silica-exposed mice compared with air-sham control mice. IL-1beta and TNFalpha expression localized to individual mononuclear cells in the alveolar spaces, groups of cells within the aggregate lesions, and scattered mononuclear cells in BALT and lymphoid nodules. Thus, cells producing IL-1beta and TNFalpha appear to be intimately associated with the evolving lesions of silicosis, and the lymphoid tissue of the lung may be important in driving the pathogenesis of this disease.

Lymphocytes, lymphokines, and silicosis.

Silicosis is characterized by mononuclear cell aggregation with mineral particles and fibrosis. Lymphocytes are abundant in these lesions. We exposed inbred strains of mice to a respirable aerosol of cristobalite silica (70 mg/m3, 5 h/d, 12 d) or shamair. Silicosis evolved over months after exposure. The silica-exposed mice showed the accumulation of lymphocytes in alveolar spaces (seen in bronchoalveolar lavage), in lung parenchymal lesions and nodules, and in enlarged bronchial-associated lymphoid tissues and thoracic lymph nodes. The lung lymphocytes were predominantly CD4+ T cells, but numerous CD8+ T cells, natural killer cells, and CD4- gammadelta-TCR+ T cells were present as well. Interferon-gamma (IFN-gamma) production was upregulated, suggesting a THelper-1-like response in silicosis. In silicotic lung tissue, mRNA transcripts for the macrophage-derived cytokines IL-12 and -18 were increased. IFN-gamma gene-deleted mice (C57Bl/6-Ifngtm1 Ts) exposed to silica developed less extensive silicosis and less lung collagen accumulation than wild-type mice. We hypothesize that there is a reiterative amplification cycle in which macrophages with silica may produce cytokines, such as IL-12 and -18, that attract and activate lymphocytes. These activated lymphocytes may then produce additional mediators that in turn attract and activate an expanded secondary population of macrophages. IFN-gamma would be a likely cause of macrophage activation in this cycle. More work is needed to understand the biological events that lead from the inhaled dust to the scarred lung, and to clarify the role of lymphocytes in this process.

Early markers of lung injury.

The goal of this study was to develop an early marker of lung injury that might change in response to exposure to a mobile source emission. Nitrogen dioxide (NO2)2 was chosen as an example of an atmospheric pollutant that is related to automobile emissions. Since reorganization of the connective tissue matrix of the lung occurs in response to injury, markers of connective tissue metabolism were selected as targets. Hydroxylysine became the marker of choice. It is an amino acid that is virtually exclusive to collagen, although it does occur in minimal amounts in other proteins. Furthermore, it is excreted in the urine, which makes it readily available for analysis using noninvasive techniques. Other markers evaluated as part of the study included angiotensin-converting enzyme as a marker of lung injury, desmosine as a marker of elastin degradation, and hydroxyproline as another marker of collagen metabolism. Male Fischer-344 rats were exposed in whole-body chambers to controlled concentrations of NO2 for various doses and periods of time. The concentrations of NO2 ranged from 0.5 to 30 parts per million (ppm); the rats were exposed for six hours per day for periods of two days to four weeks. Urine and bronchoalveolar lavage samples were collected and analyzed for the appropriate marker. In addition, pulmonary function studies and histologic examinations of the lungs were completed at selected time points. Urinary hydroxylysine concentration increased as a function of NO2 concentration during six-hour-per-day exposures for two days. This short-term exposure required relatively high doses to achieve significant changes in the hydroxylysine output. During one-week exposures to either 25 or 30 ppm NO2, there was an increase in urinary hydroxylysine associated with changes in lavage concentrations of angiotensin-converting enzyme and hydroxylysine. The lungs of these animals demonstrated histologic changes typical of oxidant injury. Four-week exposure protocols using 0.5 and 1 ppm NO2 were most interesting in terms of the sensitivity of the marker. There was minimal damage revealed by the histology and function studies, yet there were significant increases in the excretion of hydroxylysine. It appears that hydroxylysine can be indicative of exposure when other parameters are normal. It will require long-term follow-up of exposed rats to determine whether or not the change in marker concentration is predictive of damage. Hydroxylysine may be an excellent marker of exposure to oxidants in the human population. Controlled studies to establish base-line values are needed, followed by carefully controlled studies in individuals with connective tissue abnormalities of the lung.

Use of physical chemistry and in vivo exposure to investigate the toxicity of formaldehyde bound to carbonaceous particles in the murine lung.

Knowledge about the health effects of exposure to formaldehyde associated with automotive emissions is of pivotal importance in the risk assessment of this agent. Mobile sources emit many combustion-derived pollutants, including formaldehyde, in association with respirable carbon particles. Because it is hydrophilic, most of the inhaled formaldehyde is absorbed in the upper respiratory tract. However, if the organic vapor is adsorbed on respirable particles, formaldehyde may be deposited in the deep lung with the inhaled particles and may be available to interact adversely with cells along the lung parenchyma. On the respiratory surface, the alveolar macrophage phagocytic system plays the pivotal role in defending the lung against infectious agents. Susceptibility to respiratory infections is a relevant and sensitive indicator of the adverse effects of air pollution because acute and chronic exposures to a variety of air pollutants have been shown to decrease pulmonary antibacterial defenses. The goal of this research was to investigate whether exposure to formaldehyde decreases resistance to respiratory infections through dysfunctions of the alveolar macrophage phagocytic system. The study also explored whether interactions between formaldehyde and respirable carbon black particles alter susceptibility to respiratory infections and impairment of alveolar macrophage phagocytosis by delivering adsorbed formaldehyde to the deep lung with the inhaled particles. A carbon black, Regal GR, was used in these studies as a surrogate for the carbonaceous core of Diesel particulate matter. This material was selected to represent the worst-case scenario because the carbon black was expected to adsorb formaldehyde strongly. To accomplish this goal, mice were exposed to formaldehyde and to carbon black and formaldehyde combinations; increased susceptibility to respiratory infections was quantified by alveolar macrophage-dependent intrapulmonary killing of Staphylococcus aureus after an inhalation challenge with the bacterium. The salient findings of the bactericidal studies are as follows: Fifteen parts per million (ppm)* formaldehyde impaired the intrapulmonary killing of S. aureus when exposure followed the bacterial challenge. One ppm formaldehyde impaired the intrapulmonary killing of S. aureus when exposure preceded and was continued after the bacterial challenge. Coexposures to target concentrations of 3.5 mg/m3 carbon black and 2.5 ppm formaldehyde, or 10 mg/m3 carbon black and 5 ppm formaldehyde after the bacterial challenge had no effect on the intrapulmonary killing of S. aureus. Preexposure for four hours per day for four days to target concentrations of 3.5 mg/m3 carbon black and 2.5 ppm formaldehyde had no effect on the intrapulmonary killing of S. aureus when the assay was performed one day after the cessation of exposure.(ABSTRACT TRUNCATED AT 400 WORDS)

What is the relationship between hemolytic potential and fibrogenicity of mineral dusts?

The hemolytic reaction to a dust is often used as a potential indicator of fibrogenicity of silicon dioxide polymorphs. However, occasionally the hemolytic response may not correlate with the observed fibrotic response in vivo. For example, amorphous silicas are very hemolytic but have little or no fibrogenic activity. In our study, heat treatment was used to alter alpha-cristobalite, a known fibrogenic dust, to a more hydrophobic surface. Comparisons were made between heated and unheated alpha-cristobalite for hemolytic activity in vitro and for lung response in vivo. Heat treatment resulted in decreased hemolytic response, but no change in the fibrotic response occurred in vivo. In addition, the heat treatment resulted in increased initial dust accumulation, reduced short-term clearance, and enhanced long-term clearance in vivo. Increased inflammatory cell recruitment was also observed in lungs of animals exposed to alpha-cristobalite. Thus, whereas heat-induced surface changes in alpha-cristobalite markedly altered the hemolytic activity of the particles, no changes were observed in the fibrotic response.

Experimental influenza virus infection, silicon dioxide polymorphs, and pulmonary fibrogenesis.

Inhalation exposure to silicon dioxide is known to result in acute lung injury followed by pulmonary fibrosis. Recently it has been shown that the acute lung damage during influenza virus infection is also followed by a fibrogenic process. To investigate the interaction between silicon dioxide and influenza virus infection, mice were intratracheally instilled with either alpha-quartz or cristobalite and 3 d later infected by aerosol inhalation with influenza A/PR8/34 virus. At 30, 60, and 90 d after infection, groups of virus infected and noninfected mice were sacrificed and their lungs assessed for total and differential lavage cell counts, lung hydroxyproline content, and morphometric analysis. The silica polymorphs did not alter the proliferation of virus in the lungs as quantitated by infectious virus titers of lung homogenates at 1, 5, 7, 10, and 13 d after infection. In noninfected animals, cristobalite was more reactive than alpha-quartz. The virus infection, in all parameters measured at all time intervals, enhanced the overall fibrogenic response of the lungs to the mineral dusts, suggestive of an additive fibrogenic model. The data demonstrate that virus infection following silicon dioxide exposure results in an interaction that leads to an enhanced fibrogenic response.

Concomitant exposure to carbon black particulates enhances ozone-induced lung inflammation and suppression of alveolar macrophage phagocytosis.

The goal of this study was to investigate whether coexposures to carbon black and O3 result in a toxicologic interaction in the lungs as quantitated by the inflammatory response and alveolar macrophage (AM) phagocytosis. This aim was accomplished through inhalation coexposures of Swiss mice for 4 h to target concentrations of 10 mg/m3 of carbon black and 1.5 ppm O3, or exposure to either agent alone. As a control for the coexposure experiments, mice were also exposed for 4 h to carbon black, followed immediately thereafter by exposure for 4 h to O3, or vice versa. At 24 h after exposure, the lungs of the animals were lavaged for quantitation of total and differential cell counts and assessment of AM Fc-receptor-mediated phagocytosis. Exposure to carbon black did not result in an inflammatory response, nor had it any effect on AM phagocytosis. Ozone exposure resulted in an inflammatory response in the lungs and suppression of AM phagocytosis. Both biologic parameters were significantly enhanced following combined exposure to the particle and the gas. Carbon black exposure either before or after O3 had no significant effect on AM phagocytosis as compared to O3 exposure alone. These data demonstrate the toxicologic interaction of coexposures to an inert particle and O3 on well-accepted biologic markers pulmonary toxicity. The mechanism for the enhanced biologic effect may be that the carbon black particle acts as a carrier mechanism for O3 to areas in the distal lung not accessible to O3 in the gaseous phase or that O3 alters the physicochemistry of the particulate from a nontoxic to a toxic form.

Design, development and test results of a horizontal flow inhalation toxicology facility.

A horizontal flow chamber was developed for the purposes of conducting inhalation toxicology research. The chamber utilizes a unique diffuser system and pre-mixing of contaminants to achieve uniform exposure. The use of fecal catch pans eliminates exposure of animals to fecal debris from overhead animals. The chamber performance shows a rapid equilibrium in startup and shutdown.

Interferon-gamma production by specific lung lymphocyte phenotypes in silicosis in mice.

We recently described overproduction of interferon (IFN)-gamma by lung lymphocytes in mice with silicosis (11% of cells in air-control versus 19% of cells from silica-exposed mice; Davis and colleagues, Am. J. Respir. Cell Mol. Biol. 1999;20:813-824). We hypothesized that the increased IFN-gamma production might be due to selective enrichment of one lymphocyte phenotype. To test this hypothesis, small mononuclear cells from lung digest preparations of mice exposed 4 mo previously to cristobalite silica (70 mg/m(3), 12 d, 5 h/d) or to sham-air were stained for intracellular cytokines and surface antigen phenotypes, and examined by flow cytometry. Air-sham mouse lung digests included CD4(+) (16%) and CD8(+) (6%) T cells, gammadelta T-cell antigen receptor (TCR)(+) CD4(-)CD8(-) T cells (3%), natural killer (NK) cells (15%), B cells (6%), and macrophages (12%). The total number of lung lymphocytes was increased 1.7-fold in silicosis, but the phenotype frequencies did not change significantly. In the control lungs IFN-gamma was produced by three major phenotypes of lymphocytes: 5% of CD4(+) T cells, 5% of gammadelta-TCR(+) CD4(-)CD8(-) T cells, and 2% of NK cells. The percentage of each type producing IFN-gamma was increased 2- to 3-fold in silicosis. When multiplied by cell number, the increased percentages yielded a 3- to 5-fold increase in the total number of each IFN- gamma-producing phenotype in the lung. Our results demonstrate no selective phenotype enrichment but upregulated IFN-gamma production by at least three lymphocyte phenotypes. IFN-gamma may be an important signal driving lymphocyte differentiation and macrophage activation in silicosis.

Characteristics of an aerosol photometer while automatically controlling chamber dilution-air flow rate.

Trials were conducted to determine those factors that affect the accuracy of a direct-reading aerosol photometer when automatically controlling airflow rate within an exposure chamber to regulate airborne dust concentrations. Photometer response was affected by a shift in the aerosol size distribution caused by changes in chamber flow rate. In addition to a dilution effect, flow rate also determined the relative amount of aerosol lost to sedimentation within the chamber. Additional calculations were added to a computer control algorithm to compensate for these effects when attempting to automatically regulate flow based on a proportional-integral-derivative (PID) feedback control algorithm. A comparison between PID-controlled trials and those performed with a constant generator output rate and dilution-air flow rate demonstrated that there was no significant decrease in photometer accuracy despite the many changes in flow rate produced when using PID control. Likewise, the PID-controlled trials produced chamber aerosol concentrations within 1% of a desired level.

Quantitative image analysis of lung connective tissue in murine silicosis.

Pulmonary fibrosis is a disabling consequence of many lung diseases but is difficult to quantify. Lucifer yellow CH fluorescent dye (LY) appears to stain connective tissue matrix macromolecules selectively. Laser scanning confocal microscopy can quantify the intensity of fluorescence and determine the area of fluorescent material. We hypothesized that the abundance of lucifer yellow-stained matrix macromolecules in lung tissue sections could be measured by laser scanning confocal microscopy, would reflect differences between varying degrees of pulmonary fibrosis, and could be compared directly to biochemical measurements of lung collagen. We exposed C57B1/6 and 129 strains of mice by aerosol to cristobalite silica (70 mg/m3, 12 days, 5 hours/day) or sham-air and examined them 2 and 16 weeks after exposure. The area of LY-stained matrix in tissue sections was quantitated by laser scanning confocal microscopy, and total lung collagen was measured biochemically as hydroxyproline (OH-proline). The LY-stained connective tissue matrix appeared as bright linear bands in the alveolar septae, and was increased significantly by image analysis in C57B1/6 and 129 mice with silicosis 16 weeks after exposure. Total lung OH-proline was significantly increased in silica-exposed mice from both stains at both time points. Comparing all 8 groups, there was a significant linear correlation between the average area of connective tissue measured by LY stain and the total OH-proline per lung measured by chemical analysis (r = .72, P = .042). LY staining and confocal microscopy with image analysis offers a rapid technique for quantitative measurements of the extent of pulmonary fibrosis.

Review of the 4-hexylresorcinol procedure for acrolein analysis.

The purpose of this paper is to present laboratory results showing major problems with the 4-hexylresorcinol method used for acrolein analysis. A discrepancy in the analytical procedure described by ASTM and NIOSH gives rise to underestimation of acrolein levels based on the length of time the mixed reagents have been prepared prior to sampling. Underestimations by as much as 35% may occur due to the problems in the existing methodologies.

Use of peak detection circuits with single-particle detectors and multichannel analyzers.

The need, method and calibration, and results of using a peak detector interface with a Royco 220 light-scattering single-particle detector and a multichannel analyzer are presented. Two methods of peak detection are discussed. A third design is presented that is capable of handling 50 to 7500 signals/sec without introducing appreciable dead time into the system.