Rogene F. Henderson

Diesel Exhaust Is a Pulmonary Carcinogen in Rats Exposed Chronically by Inhalation

Male and female F344 rats were exposed 7 hr/day, 5 day/week for up to 30 months to automotive diesel engine exhaust at soot concentrations of 0.35, 3.5, or 7.0 mg/m3 or were sham-exposed to clean air. Rats were terminated at 6-month intervals to measure lung burdens of diesel soot and for histopathology. Other rats either died or were terminated after 30 months of exposure. Lungs were fixed, sectioned into 3-mm slices, and examined by a dissecting microscope to detect tumors. Lesions were stained and examined by light microscopy. Survival and body weight were unaffected by exposure. Focal fibrotic and proliferative lung disease accompanied a progressive accumulation of soot in the lung. The prevalence of lung tumors was significantly increased at the high (13%) and medium (4%) dose levels above the control prevalence (1%). Four tumor types, all of epithelial origin, were observed: adenoma, adenocarcinoma, squamous cyst, and squamous cell carcinoma. Logistic regression modeling demonstrated a significant relationship between tumor prevalence and both exposure concentration and soot lung burden. These results demonstrate that diesel exhaust, inhaled chronically at a high concentration, is a pulmonary carcinogen in the rat.

Comparative Pulmonary Toxicities and Carcinogenicities of Chronically Inhaled Diesel Exhaust and Carbon Black in F344 Rats

Abstract Diesel exhaust (DE) is a known pulmonary carcinogen in rats, and the carcinogenic response is known to require the presence of soot. Many estimates of human lung cancer risk from inhaled DE have been developed from rat bioassay data or from the comparative mutagenic potencies of DE soot extract and known human chemical carcinogens. To explore the importance of the DE soot-associated organic compounds in the lung tumor response of rats, male and female F344 rats were exposed chroni cally to diluted whole DE or aerosolized carbon black (CB) 16 hr/day, 5 days/week at target particle concentrations of 2.5 mg/m3 (LDE, LCB) or 6.5 mg/m3 (HDE, HCB) or to filtered air. The CB served as a surrogate for the elemental carbon matrix of DE soot. Considering both the mass fraction of solvent-extractable matter and its mutagenicity in the Ames Salmonella assay, the mutagenicity in revertants per unit particle mass of the CB was three orders of magnitude less than that of the DE soot. Both DE soot and CB particles accumulated progressively in the lungs of exposed rats, but the rate of accumulation was higher for DE soot. In general, DE and CB caused similar, dose-related, nonneoplastic lesions. CB and DE caused significant, exposure concentration-related increases, of similar magnitudes, in the incidences and prevalences of the same types of malignant and benign lung neoplasms in female rats. The incidences of neoplasms were much lower in males than females, and the mci dences were slightly higher among DE- than CB-exposed males. Survival was shortened in the CB-exposed males, and the short ened survival may have suppressed the expression of carcinoge nicity as measured by crude incidence. Logistic regression mod eling did not demonstrate significant differences between the carcinogenic potencies of CB and DE in either gender. The re sults suggest that the organic fraction of DE may not play an important role in the carcinogenicity of DE in rats.

Usefulness of lactate dehydrogenase and its isoenzymes as indicators of lung damage or inflammation

This review describes the usefulness of monitoring the activity level of lactate dehydrogenase (LDH) and its isoenzyme pattern as indicators of pathological conditions in the lungs, such as cell damage or inflammation. Cytoplasmatic cellular enzymes, like LDH, in the extracellular space, although of no further metabolic function in this space, are still of benefit because they serve as indicators suggestive of disturbances of the cellular integrity induced by pathological conditions. Since LDH is an enzyme present in essentially all major organ systems, serum LDH activity is abnormal in a large number of disorders. Although the increase in total serum LDH activity is rather nonspecific, it is proposed that measurement of LDH activity levels and its isoenzyme pattern in pleural effusion and, more recently, in bronchoalveolar lavage fluid may provide additional information about lung and pulmonary endothelial cell injury.

New approaches for the evaluation of pulmonary toxicity: bronchoalveolar lavage fluid analysis☆

Analysis of bronchoalveolar lavage fluid (BAL) is an effective method of detecting an inflammatory response in the lungs of animals in toxicological studies. Alterations in BAL that are the most sensitive indications of an inflammatory response are an increased content of serum proteins and an influx of neutrophils (PMNs). Elevation of the cytoplasmic enzyme lactate dehydrogenase (LDH) is a useful indicator of cytotoxicity. The pulmonary inflammatory response to particles (either mineral dusts or soot) in the lung includes greatly increased activities of such lysosomal enzymes as beta-glucuronidase and beta-N-acetylglucosaminidase in BAL. Examination of alterations in BAL in rats and mice during chronic exposure to high levels of diluted diesel exhaust revealed that steadily increasing levels of LDH, beta-glucuronidase, and hydroxyproline in BAL correlated better with the development of pulmonary fibrosis than did measures of an inflammatory response (protein, PMNs). Analysis of BAL has proven useful, both for detection of lung injury in toxicological screening tests and for determination of the mechanisms of developing chronic lung disease. Future work shows promise of developing assays for BAL analysis to identify the specific site or type of pulmonary injury present.

Early damage indicators in the lung. III. Biochemical and cytological response of the lung to inhaled metal salts

The validity of using the enzymatic and cytologic profile of airway fluids to indicate lung damage was tested in animals exposed by inhalation to either a known toxic metallic salt (CdCl2) or a relatively innocuous salt (CrCl3). The enzymatic and cytologic response of the airways was compared to histopathological evaluation of lung damage. Syrian hamsters were exposed to an aerosol of CdCl2 (aerodynamic diameter = 1.7 μm, σg ⋍ 1.7) to achieve an initial lung burden (ILB) of 0.6 ± 0.3 and 4.4 ± 1.2 μg of CdCl2 or to an aerosol of CrCl3 (count median diameter = 1.2 μm, σg ⋍ 1.5) to achieve an ILB of 0.7 ± 0.2 or 20 ± 10 μg of CrCl3. Animals were sacrificed at 2 hr, 1, 7, and 21 days after exposure. A sample of airay fluid was obtained by bronchopulmonary lavage and examined for the enzymatic profile of the cell-free fraction and the cytological profile of the cell fraction. Lung tissue enzyme activities were also measured and histopathologic evaluations were made on lung tissue from exposed, but nonlavaged, animals. In the lavage fluid from animals exposed to CdCl2, the enzymatic and cytologic data demonstrated a dose-response pattern and the airway response preceded enzymatic changes in the lung tissue. Tissue morphological changes correlated well with the biochemical changes. The response of the lung to CrCl3 was minimal by both morphological and biochemical evaluations. Airway enzymatic and cytologic responses were shown to be potentially useful as indicators of lung damage in toxicological screening programs.

Concepts in inhalation toxicology

An introduction to inhalation toxicology. Inhalation exposure systems. Generation and characterization of gases and vapors. Generation and characterization of test atmospheres: particles and droplets. Morphology of the respiratory tract. Lung biochemistry and intermediary metabolism. Metabolic characteristics of the respiratory tract. Deposition and clearance of inhaled particles. Pulmonary retention of particles and fibers: biokinetics and effects of exposure concentrations. Regional deposition of inhaled reactive gases. Factors modifying the disposition of inhaled organic compounds. Carcinogenic responses of the respiratory tract to inhaled toxicants. Assessment of pulmonary function and the effects of inhaled toxicants. Immunological responses of respiratory tract to inhaled materials. Biological markers in the respiratory tract. Role of cytocines in pulmonary inflammation and fibrosis. Applications of behavioral measures to inhalation toxicology. Non-carcinogenic responses of the respiratory tract to inhaled toxicants. Risk assessment for inhaled toxicants.

Early damage indicators in the lung: V. Biochemical and cytological response to NO2 inhalation☆

Abstract In an extension of earlier work on the usefulness of analysis of pulmonary lavage fluid as a probe to detect lung injury, we have examined lavage fluid from animals with a multifocal, terminal bronchiolitis induced by exposure to an oxidant gas. Syrian hamsters were exposed to concentrations of 0, 12, 17, and 22 ppm NO2 gas for 48 hr. Bronchopulmonary lavage fluids were profiled biochemically and cytologically to determine (1) the indicators of a multifocal, deep lung injury that could be detected in the lung washings and (2) the lowest level of this type of injury that could be detected by the lavage fluid screen. Lung homogenates were assayed for the enzymatic activities measured in lavage fluid and the lungs were evaluated histologically. Highest response for all parameters measured was at 2 days (end of the exposure) when the lavage fluid showed dose-dependent elevations in lactate dehydrogenase, alkaline phosphatase, acid phosphatase, glutathione reductase, and glutathione peroxidase activities, sialic acid, and total protein content, as well as increases in macrophage and neutrophil cell counts. By far the most sensitive indicator of this type of injury, as measured by the lavage fluid screen, was the neutrophil cell count, which showed a 10-fold increase even at the lowest level of exposure. The greatest change seen in the biochemical parameters measured in lavage fluid was the increase in sialic acid and protein content. There was good correlation between the degree of alteration of biochemical and cytologic indicators of injury seen in the lavage fluid and the morphological alterations seen in tissue.

Response of Rodents to Inhaled Diluted Diesel Exhaust: Biochemical and Cytological Changes in Bronchoalveolar Lavage Fluid and in Lung Tissue

The effect of long-term (24 months) inhalation of diesel exhaust on the bronchoalveolar region of the respiratory tract of rodents was assessed by serial (every 6 months) analysis of bronchoalveolar lavage fluid (BALF) and of lung tissue from F344/Crl rats and CD-1 mice (both sexes) exposed to diesel exhaust diluted to contain 0, 0.35, 3.5, or 7.0 mg soot/m3. The purpose of the study was twofold. One was to assess the potential health effects of inhaling diluted exhaust from light-duty diesel engines. The second was to determine the usefulness of BALF analysis in detecting the early stages in the development of nononcogenic lung disease and differentiating them from the normal repair processes. No biochemical or cytological changes in BALF or in lung tissue were noted in either species exposed to the lowest, and most environmentally relevant, concentration of diesel exhaust. In the two higher levels of exposure, a chronic inflammatory response was measured in both species by dose-dependent increases in inflammatory cells, cytoplasmic and lysosomal enzymes, and protein in BALF. Histologically, after 1 year of exposure, the rats had developed focal areas of fibrosis associated with the deposits of soot, while the mice, despite a higher lung burden of soot than the rats, had only a fine fibrillar thickening of an occasional alveolar septa in the high-level exposure group. Higher increases in BALF beta-glucuronidase activity and in hydroxyproline content accompanied the greater degree of fibrosis in the rat. BALF levels of glutathione (GSH) and glutathione reductase activity increased in a dose-dependent fashion and were higher in mice than in rats. Lung tissue GSH was depleted in a dose-dependent fashion in rats but was slightly increased in mice. This depletion may have played a role in the greater fibrogenic response observed in rats. Other tissue changes in enzymatic activity were small compared to changes observed in BALF. The exposure did not increase the cytochrome P-450 content of the lung in either species. The results suggest that, for the noncarcinogenic health effects reported in this paper, there is a threshold of exposure below which adverse effects were not observed. This threshold was well above environmentally relevant levels of diesel exhaust but may be in the range of some occupational exposures. The analysis of BALF proved a useful adjunct to the chronic toxicity study to quantitate the inflammatory changes accompanying the development of pulmonary disease.

Alterations in particle accumulation and clearance in lungs of rats chronically exposed to diesel exhaust

F344 rats were chronically exposed to diesel exhaust at target soot concentrations of 0 (control, C), 0.35 (low, L), 3.5 (medium, M), and 7.0 (high, H) mg/m3. Accumulated lung burdens of diesel soot were measured after 6, 12, 18, and 24 months of exposure. Parallel measurements of particle deposition and clearance were made to provide insight into the mechanisms of particle accumulation in lungs. The fractional deposition of inhaled 67Ga2O3 particles after 6, 12, 18, and 24 months of exposure and of inhaled 134Cs-fused aluminosilicate particles after 24 months were similar for all groups. Progressive increases in lung burdens of soot particles were observed in M and H exposed rats, reaching levels of 11.5 +/- 0.5 and 20.5 +/- 0.8 mg/lung (mean +/- SE), respectively, after 24 months. Rats in the L group had smaller relative increases in lung burden, reaching levels of 0.60 +/- 0.02 mg/lung after 24 months. Tracheal mucociliary clearance measurements, using 99mTc-macroaggregated albumin deposited in the trachea, showed no changes at anytime. There were statistically significant increases in clearance half-times of inhaled radiolabeled particles of 67Ga2O3 as early as 6 months at the H level and 18 months at the M level; no significant changes were seen at the L level. Rats inhaled fused aluminosilicate particles labeled with 134Cs after 24 months of diesel exhaust exposure to measure long-term components of pulmonary clearance. The long-term clearance half-times were 79 +/- 5, 81 +/- 5, 264 +/- 50, and 240 +/- 50 days (mean +/- SE) for the C, L, M, and H groups, respectively. Differences were significant between the C and both the M and H exposure groups (p less than 0.01). Lung burdens of diesel soot were more than expected at the H and M levels and were also associated with impaired particle clearance while smaller responses were observed in both burdens and clearance at the L level.

Effect of dose on the absorption and excretion of [14C]benzene administered orally or by inhalation in rats and mice

The effect of dose on the absorption and excretion of [14C]benzene was studied using 13-week old male F344/N rats, Sprague-Dawley rats, and B6C3F1 mice. Gastrointestinal absorption of benzene administered by gavage was greater than 97% in these species for doses between 0.5 and 150 mg benzene/kg body wt. At oral doses below 15 mg/kg, greater than 90% of the 14C excreted was in the urine as nonethylacetate extractable material. Above 15 mg/kg, in both rats and mice, an increasing percentage of the administered benzene was exhaled unmetabolized, suggesting saturation of metabolic pathways. Above 50 mg/kg, total metabolites (as determined by 14C in the urine, feces, and carcass after 2 days) were not linearly related to administered dose. Total metabolites per unit body weight was equal in F344/N rats and B6C3F1 mice at gavage doses up to 50 mg/kg; however, total metabolites in mice did not increase at higher doses. For inhalation exposures, the percentage of inhaled benzene that was absorbed and retained during a 6-hr exposure decreased from 33 +/- 6% (mean +/- standard deviation) to 15 +/- 9% in rats, and from 50 +/- 15 to 10 +/- 2% in mice as the exposure concentration was increased from approximately 26 to 2600 micrograms/liter (10 to 1000 ppm at 615 Torr, 23 degrees C). Total metabolite formation was exponentially related to the benzene exposure concentration with one-half the maximal amount of metabolite formation occurring at 220 micrograms/liter (84 ppm) for B6C3F1 mice and 650 micrograms/liter (250 ppm) for F344/N rats. Total metabolites were higher in mice than in rats at any of the vapor concentrations used due mainly to the higher amount inhaled by mice. Saturation of overall metabolism in mice but not in rats at high doses by both routes of administration indicates species differences in metabolism of benzene.