Comparison of Toxicological Models for Evaluation of Air Pollutants: Response of the Pulmonary Alveolar Macrophage to Hexavalent Chromium

Galvin, Jennifer Baker

01 May 1981

This study was designed to accomplish two primary objectives: (1) to compare two test methods commonly used to evaluate toxicity of inhaled air pollutants, and (2) to observe the response as measured by each of the methods, of pulmonary alveolar macrophages exposed to 2μg hexavalent chromium. The firs t method evaluated featured use of intratracheal injections to simulate live inhalation exposures, and the second required exposure of macrophages cultured on petri plates. Pulmonary alveolar macrophages harvested from Long Evans rats were used. The two cell function parameters measured in the evaluations were chemiluminescence and oxygen consumption (which was determined for cells at rest and during phagocytosis). These two tests have been shown to be sensitive indicators of macrophage damage. Results of CL output and oxygen consumption revealed the two methods were significantly different. Evaluation of macrophages from live animals treated with CrO3 or CaCrO4showed no differences between their respective untreated controls as determined by measurement of their chemiluminescence production or of oxygen consumption rates. Alveolar macrophages that were cultured in media during treatment with the same two forms of hexavalent chromium showed statistically significant differences from untreated controls. These comparisons indicate that choices of investigative toxicological models influence interpretation of data recorded.

Comparison of Toxicological Models

Evaluation of Air Pollutants

Pulmonary Alveolar Macrophage

Hexavalent Chromium

Chemistry

The effect of maternal nicotine exposure on rat lung tissue morphology. ' a light and electron microscopic study

Woolward, Keryn Miles

January 1991

Masters of Science / The infants of women who smoke during pregnancy have a lower birth mass than those born of women who abstain. Animal studies reveal that reduced growth due to maternal nicotine exposure during gestation is accompanied by lung hypoplasia. Biochemical analysis suggests that these lungs contain more cells which implies that lung damage occurs. In this study we examined the in vivo effects of maternal nicotine exposure (lmg/Kg/day), the equivalent of 32 cigarettes per day, on the following parameters of fetal and neonatal Wistar rat lung:(i) the content and distribution of glycogen in fetal and neonatal lung (ii) the status of connective tissue in neonatal lung (iii) the cell composition of the alveoli in neonatal lung. Fetal rat lungs of ages 17, 18, 19 and 20 days and neonatal lungs of 1, 7, 14 and 21 day old pups were used. Light microscope techniques and special stains were used to investigate glycogen, connective tissue, macrophage numbers and morphological status of the lungs. Fetal rat lungs of ages 17, 18, 19 and 20 days and neonatal lungs of 1, 7, 14 and 21 day old pups were used. Light microscope techniques and special stains were used to investigate glycogen, connective tissue, macrophage numbers and morphological status of the lungs. Transmission electron microscope (TEM) techniques were employed to investigate the characteristics and composition of the alveolus The results show clearly that maternal nicotine exposure elevates pulmonary alveolar macrophage numbers'(PAM's) and lung glycogen levels. The quantity of elastic fibres in 1 day old neonates was significantly reduced but no changes in the quantity of reticulin and collagen fibres was observed. As a result of this change in connective tissue status, emphysema-like lesions and alveolar collapse was evident in the lungs of nicotine-exposed pups. TEM investigations revealed that changes to the composition of alveoli occurred. These included increased numbers of type II pneumocytes with high numbers of lamellar bodies with degenerative changes. Thickening of the blood-air barrier was also observed. The effect of maternal nicotine exposure has been documented in this study. However, it has not been possible to pinpoint the mechanisms involved but explanations have been proposed. Further research is required to elucidate the mechanisms by which nicotine produces these effects. Information thus obtained could help prevent the harmful effects to the fetus and neonate caused by smoking during pregnancy.

Glycogen

Transmission electron microscope (TEM)

In vivo

Emphysema

Parenchyma

Hypoplasia