Gary E. Hatch

Inhalable particles and pulmonary host defense: In vivo and in vitro effects of ambient air and combustion particles

The ability of particulate air pollutants (and possible constituents) to alter pulmonary host defenses was examined using an in vitro alveolar macrophage cytotoxicity assay and an in vivo bacterial infectivity screening test which employed intratracheal injection of the particles. A wide range of response between particles was seen at the 1.0-mg/ml level in vitro and the 0.1-mg/mouse level in vivo. A sample of fluidized-bed coal fly ash, bentonite, asbestos, some ambient air particles, and heavy metal oxides greatly increased susceptibility to pulmonary bacterial infection. Most coal fly ash samples and some air particles caused moderate increases in infectivity, while diesel particulates, volcanic ash, and crystalline silica caused only small increases. Cytotoxic effects on macrophages in vitro were observed with most of the particles. The in vivo and in vitro assays produced a similar ranking of toxicity; however, not all particles that were highly cytotoxic were potent in increasing bacterial infectivity. Increased toxicity measurable by either assay often appeared to be associated with small size or with the presence of metal in the particles.

Protein accumulation in lung lavage fluid following ozone exposure

Abstract Accumulation of protein in lung lavage fluid was used as an indicator of pulmonary damage following exposure of guinea pigs to O 3 . Exposure of animals to 510, 1000, or 1960 μg/m 3 (0.26, 0.51, or 1.0 ppm) of O 3 for 72 hr resulted in significantly elevated levels of lavage fluid protein when compared to that of air controls. This effect was not observed in animals exposed to 196 μg O 3 /m 3 (0.10 ppm). When exposure time was reduced to 3 hr, the O 3 -induced protein accumulation in lavage fluids was undetectable unless the time of lavage was delayed 10–15 hr following the exposure. Under these conditions, elevated protein content was seen in lung lavage fluids obtained from animals exposed to O 3 ranging from 510 to 1470 μg O 3 /m 3 (0.26-0.75 ppm) and a dose relationship between the amount of protein accumulation in the lung and the concentration of O 3 to which the animals were exposed was observed. Vitamin C deficiency did not enhance this O 3 -induced lesion in guinea pigs. The dose relationship has also been confirmed by polyacrylamide gel electrophoresis of the lavage fluids. Lung lavage fluid protein content in animals exposed to 353 μg O 3 /m 3 (0.18 ppm) for 8 hr/day for 5 or 10 consecutive days was not different from that of air controls.

Species comparison of acute inhalation toxicity of ozone and phosgene

A comparison of the concentration-response effects of inhaled ozone (O3) and phosgene (COCl2) in different species of laboratory animals was made in order to better understand the influence of the choice of species in inhalation toxicity studies. The effect of 4-h exposures to ozone at concentrations of 0.2, 0.5, 1.0, and 2.0 ppm, and to COCl2 and 0.1, 0.2, 0.5, and 1.0 ppm was determined in rabbits, guinea pigs, rats, hamsters, and mice. Lavage fluid protein (LFP) accumulation 18-20 h after exposure was used as the indicator of O3- and COCl2-induced pulmonary edema. All species had similar basal levels of LFP (250-350 mg/ml) when a volume of saline that approximated the total lung capacity was used to lavage the collapsed lungs. Ozone effects were most marked in guinea pigs, which showed significant effects at 0.2 ppm and above. Mice, hamsters, and rats showed effects at 1.0 ppm O3 and above, while rabbits responded only at 2.0 ppm O3. Phosgene similarly affected mice, hamsters, and rats at 0.2 ppm and above, while guinea pigs and rabbits were affected at 0.5 ppm and above. Percent recovery of lavage fluid varied significantly between species, guinea pigs having lower recovery than other species with both gases. Lavage fluid recovery was lower following exposure to higher levels of O3 but not COCl2. Results of this study indicate that significant species differences are seen in the response to low levels of O3 and COCl2. These differences do not appear to be related in a simple manner to body weight.

Age, Strain, and Gender as Factors for Increased Sensitivity of the Mouse Lung to Inhaled Ozone

Ozone (O(3)) is a respiratory irritant that leads to airway inflammation and pulmonary dysfunction. Animal studies show that neonates are more sensitive to O(3) inhalation than adults, and children represent a potentially susceptible population. This latter notion is not well established, and biological mechanisms underlying a predisposition to pollution-induced pulmonary effects are unknown. We examined age and strain as interactive factors affecting differential pulmonary responses to inhaled O(3). Male and female adult mice (15 weeks old) and neonates (15-16 days old) from eight genetically diverse inbred strains were exposed to 0.8 ppm O(3) for 5 h. Pulmonary injury and lung inflammation were quantified as total protein concentration and total polymorphonuclear neutrophil (PMN) number in lavage fluid recovered 24-h postexposure. Dose-response and time-course curves were generated using SJL/J pups, and (18)O lung burden dose was assessed in additional mice. Interstrain differences in response to O(3) were seen in neonatal mice: Balb/cJ and SJL/J being most sensitive and A/J and 129x1/SvJ most resistant. The PMN response to O(3) was greater in neonates than in adults, specifically for SJL/J and C3H/HeJ strains, independent of dose. Small gender differences were also observed in adult mice. Variation in protein concentrations and PMN counts between adults and pups were strain dependent, suggesting that genetic determinants do play a role in age-related sensitivity to O(3). Further research will help to determine what genetic factors contribute to these heightened responses, and to quantify the relative contribution of genes vs. environment in O(3)-induced health effects.

Application of the EPR spin-trapping technique to the detection of radicals produced in vivo during inhalation exposure of rats to ozone

Ozone is known to induce lipid peroxidation of lung tissue, although no direct evidence of free radical formation has been reported. We have used the electron paramagnetic resonance (EPR) spin-trapping technique to search for free radicals produced in vivo by ozone exposure. The spin trap alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN) was administered ip to male Sprague-Dawley rats. The rats were then exposed for 2 hr to either 0, 0.5, 1.0, 1.5, or 2.0 ppm ozone with 8% CO2 to increase their respiratory rate. A six-line 4-POBN/radical spin adduct signal (aN = 15.02 G and a beta H = 3.27 G) was detected by EPR spectroscopy in lipid extracts from lungs of rats treated with 4-POBN and then exposed to ozone. Only a weak signal was observed in the corresponding solution from rats exposed to 0 ppm ozone (air with CO2 only). The concentration of the radical adduct increased as a function of ozone concentration. After administration of 4-POBN, rats were exposed for either 0.5, 1.0, 2.0, or 4.0 hr to either 0 or 2.0 ppm ozone (with CO2). The radical adduct concentration of the ozone-exposed groups at exposure times of 2.0 and 4.0 hr was significantly different from that of the corresponding air control groups. A correlation was observed between the radical adduct concentration and the lung weight/body weight ratio. These results demonstrate that ozone induces the production of free radicals in rat lungs during inhalation exposure and that radical production may be involved in the induction of pulmonary toxicity by ozone. This is the first direct evidence for ozone-induced free radical production in vivo.

Pulmonary Structural and Extracellular Matrix Alterations in Fischer 344 Rats Following Subchronic Phosgene Exposure

Phosgene, an acylating agent, is a very potent inducer of pulmonary edema. Subchronic effects of phosgene in laboratory animals are not well characterized. The purpose of the study was to elucidate potential long-term effects on collagen and elastin metabolism during pulmonary injury/recovery and obtain information about the concentration x time (C x T) behavior of low levels of phosgene. Male Fischer 344 rats (60 days old) were exposed either to clean air or phosgene, 6 hr/day: 0.1 ppm (5 days/week), 0.2 ppm (5 days/week), 0.5 ppm (2 days/week), and 1.0 ppm (1 day/week), for 4 or 12 weeks. A group of rats was allowed clean air recovery for 4 weeks after 12 weeks of phosgene exposure. This exposure scenario was designed to provide equal C x T product for all concentrations at one particular time point except for 0.1 ppm (50% C x T). Phosgene exposure for 4 or 12 weeks increased lung to body weight ratio and lung displacement volume in a concentration-dependent manner. The increase in lung displacement volume was significant even at 0.1 ppm phosgene at 4 weeks. Light microscopic level histopathology examination of lung was conducted at 0.0, 0.1, 0.2, and 1.0 ppm phosgene following 4 and 12 and 16 weeks (recovery). Small but clearly apparent terminal bronchiolar thickening and inflammation were evident with 0.1 ppm phosgene at both 4 and 12 weeks. At 0.2 ppm phosgene, terminal bronchiolar thickening and inflammation appeared to be more prominent when compared to the 0.1 ppm group and changes in alveolar parenchyma were minimal. At 1.0 ppm, extensive inflammation and thickening of terminal bronchioles as well as alveolar walls were evident. Concentration rather than C x T seems to drive pathology response. Trichrome staining for collagen at the terminal bronchiolar sites indicated a slight increase at 4 weeks and marked increase at 12 weeks in both 0.2 and 1.0 ppm groups (0.5 ppm was not examined), 1.0 ppm being more intense. Whole-lung prolyl hydroxylase activity and hydroxyproline, taken as an index of collagen synthesis, were increased following 1.0 ppm phosgene exposure at 4 as well as 12 weeks, respectively. Desmosine levels, taken as an index of changes in elastin, were increased in the lung after 4 or 12 weeks in the 1.0 ppm phosgene group. Following 4 weeks of air recovery, lung hydroxyproline was further increased in 0.5 and 1.0 ppm phosgene groups. Lung weight also remained significantly higher than the controls; however, desmosine and lung displacement volume in phosgene-exposed animals were similar to controls. In summary, terminal bronchiolar and lung volume displacement changes occurred at very low phosgene concentrations (0.1 ppm). Phosgene concentration, rather than C x T product appeared to drive toxic responses. The changes induced by phosgene (except of collagen) following 4 weeks were not further amplified at 12 weeks despite continued exposure. Phosgene-induced alterations of matrix were only partially reversible after 4 weeks of clean air exposure.

Nitrogen dioxide exposure and lung antioxidants in ascorbic acid-deficient guinea pigs☆

We have previously found that ascorbic acid (AA) deficiency in guinea pigs enhances the pulmonary toxicity of nitrogen dioxide (NO2). The present study showed that exposure to NO2 (4.8 ppm, 3 hr) significantly increased lung lavage fluid protein (a sensitive indicator of pulmonary edema) only in guinea pigs fed rabbit chow (a diet not supplemented with vitamin C) for at least 7 days, at which time lung AA was about 50% of normal. The rabbit chow diet did not cause reduced body weight as did commercial synthetic scorbutic diets, even when they were supplemented with AA. After 14 days of feeding rabbit chow, lung AA was reduced to 15% of control. At this time, alpha-tocopherol (AT) in the same lungs was reduced to 85% of control, and lung nonprotein sulfhydryls (NPSH) were increased to 114% of control. Exposure of the guinea pigs to NO2 (4.5 ppm, 16 hr) increased wet lung weight and further altered the antioxidants in deficient (but not normally fed) animals in the following manner: NPSH content was increased to 130% of control, AT was decreased to 74% of control, and AA was increased from 15 to 50% of control. These findings suggest that depletion of AA in guinea pigs removes an important defense against NO2. The lung appears to be able to partially compensate for the dietary lack of antioxidant by accumulating AA from other tissues and by increasing NPSH concentrations. However, sufficient exposure to NO2 leads to oxidation of AT and pulmonary edema. Conditions in which NO2 produced edema were accompanied by only a slight consumption of AT, and no detectable oxidation of lung AA or NPSH.

Pulmonary biochemical effects of inhaled phosgene in rats

Three exposure regimens were used to study the time course of indicators of lung damage and recovery response to single or repeated exposures to phosgene (COCl2). Rats were sacrificed immediately or throughout a 38-d recovery period after inhalation of 1 ppm COCl2 for 4 h, at intervals during a 7-h exposure to 1 ppm phosgene, or at several time points throughout a 17-d exposure to 0.125 and 0.25 ppm COCl2 (4 h/d, 5 d/wk) and during a 21-d recovery period. Regimen 1 revealed significantly elevated lung wet weight, lung nonprotein sulfhydryl (NPSH) content, and glucose-6-phosphate dehydrogenase (G6PD) activity that stayed elevated for up to 14 d. A significant decrease in body weight and food intake was observed 1 d after exposure. Regimen 2 caused a slight depression in NPSH content but did not affect G6PD activity. Regimen 3 animals showed sustained elevations in lung wet weight, NPSH content, and G6PD activity after 7 d of exposure. No significant changes in these endpoints were observed for the 0.125 ppm COCl2 group. No consistent elevation in hydroxyproline content was seen at either exposure concentration. Light microscopic examination of lung tissue exposed to 0.25 ppm COCl2 for 17 d revealed moderate multifocal accumulation of mononuclear cells in the centriacinar region. In summary, exposure to COCl2 caused changes similar in most ways to those observed for other lower-respiratory-tract irritants.

Effects of Depletion of Ascorbic Acid or Nonprotein Sulfhydryls on the Acute Inhalation Toxicity of Nitrogen Dioxide, Ozone, and Phosgene

AbstractThe effect of depleting lung ascorbic acid (AH2) and nonprotein sulfhydryls (NPSH) on the acute inhalation toxicity of nitrogen dioxide (NO2), ozone (O3), and phosgene (COCl2) was investigated in guinea pigs. The increase in bronchoalveolar lavage (BAL) fluid protein (an indicator of alveolar-capillary damage leading to increased permeability) was measured 16–78 h following a 4-h exposure to the gas in animals deficient in AH2 or NPSH. Gas concentrations were chosen that produced low but significant increases in BAL protein. Lung AH2 was lowered to about 20% of control by feeding rabbit chow for 2 wk. Lung NPSH was lowered to about 50% of control by injecting a mixture of buthionine S, R-sulfoximine (BSO) and diethylmaleate (OEM) (2.7 and 1.2 mmol/kg, respectively). BSO/DEM did not affect the lung concentrations of AH2 or α-tocopherol. AH2 depletion caused a fivefold and a threefold enhancement in the toxicity of 5 ppm and 10 ppm NO2, and a sixfold enhancement in the toxicity of 0.5 ppm O3, but di...

Inhalation studies of Mt. St. Helens volcanic ash in animals: II. Lung function, biochemistry, and histology

Rats were exposed by inhalation to 9.4 mg/m3 size-fractionated volcanic ash for 5 days (2 hr/day) and examined for changes in pulmonary function and histology for periods of up to 1 year. Fine-mode volcanic ash, SO2, and a combination of ash and SO2 produced no observable effects in normal rats and rats with elastase-induced emphysema. However, there was a mild irritant response to SO2 which was not influenced by the volcanic ash. Rats injected intratracheally with fine-mode volcanic ash or saline showed no evidence of pulmonary alterations after 6 months. Those injected with coarse-mode volcanic ash showed minor pulmonary functional changes, histologically detectable alveolitis, and small increases in lung weight. In contrast, quartz-injected rats showed large alterations in pulmonary function, lung weight, hydroxyproline levels, and large areas of lung consolidation and fibrosis.