L. van Bree

Diesel Exhaust Particles Induced Release of Interleukin 6 and 8 by (Primed) Human Bronchial Epithelial Cells (Beas 2b) In Vitro

Several epidemiological studies have recently shown associations of increased premature mortality rates with ambient paniculate air pollution. Diesel exhaust particles (DEP) may constitute an important part of (ultra)fine particulate air pollution in urban areas and may therefore contribute to its toxicity. Epithelial lining of the respiratory tract may be the first target of the toxic effects of DEP, that upon exposure may release pro-inflammatory mediators such as interleukin 6 and 8 (IL-6, IL-8), ultimately causing airway tissue damage and immune alterations. In this study the effects of in vitro DEP exposure (0.04–0.33 mg/mL) on IL-6, IL-8 production by a human bronchial epithelial cell line (BEAS-2B) were investigated. For comparison, the production of interleukins during exposure to silica and titanium oxide (TiO2) were also studied, representing relatively toxic and non-toxic particles, respectively. Scanning and transmission electron microscopy showed that the size of the DEP particles ranged betw...

Glutathione pathway enzyme activities and the ozone sensitivity of lung cell populations derived from ozone exposed rats

Rats were exposed to 1.5 +/- 0.1 mg ozone/m3 for 4 days and the activities of glucose-6-P dehydrogenase (G6PDH), glutathione reductase (GR) and glutathione peroxidase (GSHPx) were measured in the cytosolic fraction of lungs from exposed and control rats. Enzyme activities were also measured in isolated alveolar macrophages and type II cells. After ozone exposure enzyme activities, expressed per gram of protein, showed the following changes. G6PDH activity was increased (P less than 0.001) in the whole rat lung and showed the same tendency in isolated alveolar macrophages and type II cells. GR activity did not change significantly neither in whole lungs, nor in isolated cell populations. GSHPx activity was increased (P less than 0.001) in whole lung homogenates, and was also markedly increased in both alveolar macrophages (P less than 0.05) and type II cells (P less than 0.01) isolated from ozone-exposed rats. From these results it was concluded that biochemical changes measured in whole lung homogenates might reflect biochemical changes that occur within specific cell types. Furthermore, it was demonstrated, using an in vitro ozone exposure system, that lung cell populations isolated from ozone-exposed rats, in spite of their marked increase in GSHPx activity, did not show a decreased ozone sensitivity compared to cells from unexposed rats, as determined by trypan blue exclusion or phagocytosis. So an increase in GSHPx activity might not be related to an increased cellular resistance to ozone.

Qualitative and quantitative changes in cytochrome P-450-dependent xenobiotic metabolism in pulmonary microsomes and isolated Clara cell populations derived from ozone-exposed rats.

The effect of a prolonged ozone exposure (1.6 mg ozone/m3; 7 d; 24 h/d) on pulmonary cytochrome P-450-dependent xenobiotic metabolism was studied both in whole rat lung as well as in isolated bronchiolar Clara cell preparations. Ozone exposure was demonstrated to result in significant quantitative but also qualitative changes. All components of the pulmonary microsomal electron transport system appeared to be significantly increased in the lungs of exposed animals both per lung and per gram lung, although increases were no longer observed when expressed per milligram microsomal lung protein. Remarkably, it was demonstrated that the increases in the components of the pulmonary cytochrome P-450 system were not accompanied by a concomitant increase in all cytochrome P-450-dependent substrate conversions. In whole-lung microsomes ethoxycoumarin O-deethylase and ethoxyresorufin O-deethylase activities were unchanged or even significantly reduced when expressed per lung, per gram lung, per milligram microsomal protein, or per picomole cytochrome P-450. In contrast to these observations, pentoxyresorufin O-dealkylation appeared to be significantly increased upon ozone exposure when expressed per lung, per gram lung, and even per picomole cytochrome P-450. Clara cell populations isolated from ozone exposed rats showed a comparable qualitative shift in cytochrome P-450-dependent substrate conversion characteristics. On a cellular basis, ozone exposure resulted in a significant reduction of ethoxycoumarin and ethoxyresorufin O-deethylation and did not affect pentoxyresorufin O-dealkylase activity. Additional experiments, in which ozone-mediated inactivation of microsomal cytochrome P-450-dependent substrate metabolism was studied in vitro, demonstrated that the qualitative changes observed after in vivo exposure cannot be ascribed to a disproportional inactivation of different cytochrome P-450 isoenzymes. Based on these results and on lung morphometrics and cell isolation data presented, the observed effects should rather be ascribed to (1) the proliferation of cytochrome P-450 containing cell populations and (2) intrinsic cellular biochemical changes. The quantitative and qualitative ozone-induced changes in pulmonary cytochrome P-450-linked enzyme characteristics in whole lung and within specific lung cells, as demonstrated in the present study, may be expected to have important implications for the toxicity of xenobiotics whose (de)toxification depends on pulmonary cytochrome P-450-dependent metabolism.

Health effects of coarse particles in ambient air: messages for research and decision-making

Health effects of coarse particles in ambient air : messages for research and decision-making.

ATTENUATION AND RECOVERY OF PULMONARY INJURY IN RATS FOLLOWING SHORT-TERM, REPEATED DAILY EXPOSURE TO OZONE

Controlled human and epidemiology studies have demonstrated that during repeated exposure to ozone (O 3) attenuation of lung function responses may occur. It is yet unknown whether inflammatory and biochemical effects in lower airways of humans, as observed upon single O 3 exposure, also show a diminutive response following repeated exposure to O 3. The aim of this study was to investigate inflammatory, permeability, and histopathological responses in lungs of rats following repeated daily O 3 exposure and to study the time course of attenuation and recovery of these effects using single O 3 challenges at various postexposure times. To aid in animal-to-human extrapolation, this study and a previously reported human study (Devlin et al., 1997) were designed with similar protocols. Wistar rats were exposed for 5 consecutive days to 0.4 ppm O 3 for 12 h/night. Subsequently, the time course of postexposure recovery was determined by a single challenge of 12 h to 0.4 ppm O 3 after a 5-, 10-, 15-, or 20-day recovery period. Broncho-alveolar lavage (BAL) examination and histopathology were performed 12 h after this O 3 challenge. To quantify the magnitude of the O 3 response, results were compared with a group exposed only once for 12 h to 0.4 ppm O 3 and sacrificed simultaneously. The results demonstrate that a single exposure of 0.4 ppm O 3 causes marked permeability and inflammatory responses in lower airways of rats, as evidenced by enhanced BAL fluid levels of proteins, fibronectin, interleukin (IL)-6, and inflammatory cells. However, 5 days of exposure to 0.4 ppm O 3 for 12 h/night resulted in a complete disappearance of these responses, resulting in BAL fluid values that were not different from those observed in unexposed controls. Postexposure analyses of pulmonary response to O 3 challenges demonstrated that these attenuated responses show a gradual recovery. The data indicate that with respect to BAL fluid levels of albumin, IL-6, and number of macrophages and neutrophils, the period for lung tissue to regain its full susceptibility and responsiveness to O 3 following a 5-day preexposure period is approximately 15-20 days. Remarkably, the total protein and fibronectin responses in BAL fluid still exhibited an attenuated response to an O 3 challenge at 20 days postexposure. Morphometry (number of BrdU-labeled cells in terminal bronchiolar epithelium, and number of alveolar macrophages) showed that after a recovery of 5-10 days following a 5-day preexposure the response to a challenge was identical to that after a single exposure. These results suggest that complete repair from lower airway inflammation caused by short-term, repeated exposure to O 3 may take longer than previously assumed.

Protection against paracetamol-induced hepatotoxicity by acetylsalicylic acid in rats☆

Acetylsalicylic acid (ASA) given simultaneously with paracetamol decreased paracetamol-induced hepatotoxicity (measured by plasma transaminase activities as well as histology) without any effect on glutathione depletion, indicating that ASA prevents a process (or processes) subsequent to the metabolic activation of paracetamol. Delayed treatment with ASA also reduced paracetamol-induced liver toxicity, suggesting that reduction of the absorption rate of paracetamol does not contribute essentially to the protection by ASA. Combinations of paracetamol and ASA may have potential use in the development of safer analgesic combinations containing paracetamol (or ASA).

TIME STUDY ON DEVELOPMENT AND REPAIR OF LUNG INJURY FOLLOWING OZONE EXPOSURE IN RATS

The aim of this study was to investigate the time course of lung injury in rats during acute and subchronic ozone exposure and during postexposure recovery. Rats were continuously exposed to 0.4 ppm ozone (~0.8 mg O 3 /m 3) for 1, 3, 7, 28, or 56 days. Recovery from 3 days of exposure was studied at day 7, 14, and 28; recovery from 7 days of exposure was studied at day 14, 28, and 56, recovery from 28 days of exposure was studied at day 35 and 56, and recovery from 56 days of exposure was studied at day 136. The study included a correlated biochemical and morphological analysis of inflammatory responses, structural changes, and collagen content. The acute inflammatory response, as measured by an increase of polymorphonuclear cells and plasma protein in bronchoalveolar lavage (BAL) fluid, reached a maximum at day 1 and resolved largely within 6 days during ongoing exposure. Numbers of macrophages in BAL fluid increased progressively up to day 56, and slowly returned to near control levels when exposure was followed by postexposure recovery. Histological examination and morphometry of the lungs revealed centriacinar inflammatory responses throughout ozone exposure. Centriacinar thickening of septa was observed at day 7. Ductular septa, thickened progressively at days 7, 28, and 56 of exposure, showed increased collagen upon exposure at day 28, which was further enhanced at exposure at day 56. Increased collagen content in lungs, as measured biochemically by hydroxyproline concentration, was observed at exposure day 56. Collagen content was not different from control at day 56 when 7 or 28 days of exposure was followed by postexposure recovery. After continuous ozone exposure, respiratory bronchioles were present in an increasing degree, and remained present after a recovery period. The results of this study clearly show that after continuous exposure to O 3 some acute effects, such as protein and albumin content, and neutrophil influx in BAL fluid, returned to control levels within a few days. However, other parameters, such as the alveolar macrophage response and structural changes such as the presence of terminal bronchioles, thickening of ductular septa by enhanced cellularity, and collagen formation, persisted or progressively increased during continued exposure. Postexposure recovery seems to partly resolve these subchronic responses (macrophages response, septal cellularity), whereas other effects (collagen increase and respiratory bronchioles formation) do not disappear.The aim of this study was to investigate the time course of lung injury in rats during acute and subchronic ozone exposure and during postexposure recovery. Rats were continuously exposed to 0.4 ppm ozone ( approximately 0.8 mg O(3)/m(3)) for 1, 3, 7, 28, or 56 days. Recovery from 3 days of exposure was studied at day 7, 14, and 28; recovery from 7 days of exposure was studied at day 14, 28, and 56, recovery from 28 days of exposure was studied at day 35 and 56, and recovery from 56 days of exposure was studied at day 136. The study included a correlated biochemical and morphological analysis of inflammatory responses, structural changes, and collagen content. The acute inflammatory response, as measured by an increase of polymorphonuclear cells and plasma protein in bronchoalveolar lavage (BAL) fluid, reached a maximum at day 1 and resolved largely within 6 days during ongoing exposure. Numbers of macrophages in BAL fluid increased progressively up to day 56, and slowly returned to near control levels when exposure was followed by postexposure recovery. Histological examination and morphometry of the lungs revealed centriacinar inflammatory responses throughout ozone exposure. Centriacinar thickening of septa was observed at day 7. Ductular septa, thickened progressively at days 7, 28, and 56 of exposure, showed increased collagen upon exposure at day 28, which was further enhanced at exposure at day 56. Increased collagen content in lungs, as measured biochemically by hydroxyproline concentration, was observed at exposure day 56. Collagen content was not different from control at day 56 when 7 or 28 days of exposure was followed by postexposure recovery. After continuous ozone exposure, respiratory bronchioles were present in an increasing degree, and remained present after a recovery period. The results of this study clearly show that after continuous exposure to O(3) some acute effects, such as protein and albumin content, and neutrophil influx in BAL fluid, returned to control levels within a few days. However, other parameters, such as the alveolar macrophage response and structural changes such as the presence of terminal bronchioles, thickening of ductular septa by enhanced cellularity, and collagen formation, persisted or progressively increased during continued exposure. Postexposure recovery seems to partly resolve these subchronic responses (macrophages response, septal cellularity), whereas other effects (collagen increase and respiratory bronchioles formation) do not disappear.

Attenuation of acute lung injury by ozone inhalation : the effect of low level pre-exposure

The attenuating influence of a pre-exposure of rats to a low concentration of ozone (O3) for 7 days on a subsequent O3 challenge was investigated. Effects of O3 were quantified by measuring indicators of lung permeability and inflammation in bronchoalveolar lavage fluid. The results suggest that pre-exposure to relatively low levels of O3 produces a diminished permeability response in lower airways of rats upon a following challenge with a higher level of O3. Extrapolated to human exposure situations, these data suggest that health effect evaluation of repeated exposure periods of enhanced O3 levels is rather complex and needs further investigation.

PATHOLOGICAL AND IMMUNOLOGICAL EFFECTS OF RESPIRABLE COAL FLY ASH IN MALE WISTAR RATS

In this study the effects of inhalatory exposure to coal fly ash on lung pathology and the immune system in rats were examined. Rats were exposed to 0, 10, 30, or 100 mg/m(3) coal fly ash (6 h/day, 5 days/wk) for 4 wk, or to 0 and 100 mg/m(3) for 1 wk, and for 1 wk followed by a recovery in clean air of 3 wk. A concentration-related increase in lung weight was found starting from 30 mg/m(3) coal fly ash. After exposure to 100 mg/m(3), a time-related deposition of free particles in the lungs was observed as well as a time-related number of coal fly ash particles phagocytized in alveolar macrophages. Histological examination revealed increased cellularity in alveolar septa, consisting mainly of mononuclear cell infiltrate, proliferated type II cells, and a slight fibrotic reaction. After a recovery period of 3 wk the histological picture was identical to that after 1 wk of exposure, indicating no significant recovery. No toxicological significant changes were found in the hematological, clinical chemistry, or urine parameters. Effects both on nonspecific defense mechanisms and on specific immune responses were noted. With regard to the immune function in the draining lymph nodes of the lung, a significantly increased number of both T and B lymphocytes was observed. The ratio of both cell types was not changed in either of the groups. In serum of exposed rats a significant increase of up to 150% of the immunoglobulin A (IgA) content was found. The number and phagocytic capacity of macrophages were significantly increased, while the killing of Listeria bacteria per cell ex vivo/in vitro remained unchanged. Natural killer (NK) activity in pulmonary cell suspensions was slightly stimulated in rats exposed for 4 wk to 10 and 30 mg/m(3), whereas an exposure to 100 mg/m(3) resulted in a slight decrease; however, both changes were not significant. In conclusion, the alterations in lung histopathology and immunity, observed in a dose and exposure time relation at concentrations up to and including 100 mg/m(3) coal fly ash, may be considered an adverse response of the host to inhalation of particulate matter. Whether these observed alterations may effect the host resistance must be learned from infection studies.

A meta-level analysis of major trends in environmental health risk governance

Internationally but also within countries, large differences exist regarding how environmental health risks (EHRs) are governed. Despite these differences, at a meta‐level some general trends can be discerned that may point to a convergence of EHR governance regimes. One, EHR governance regimes are increasingly taking into account cost‐benefit considerations, sectoral goals outside the health risk domain, public concerns and stakeholder interests in early stages of decision‐making. Two, EHR objectives are increasingly integrated in other, sectoral policies such as land use planning. Three, an increased differentiation of EHR standards is observed (partly as a consequence of the former characteristic). Still little systematic empirical research has been conducted on the dynamics in EHR governance regimes and their causes, on what EHR governance regimes have produced in terms of (perceived) risk reduction and on how these results can be explained. This paper proposes a systematic framework for analysing, explaining and evaluating shifts in EHR governance regimes. The framework in turn is applied to examine and understand the shift towards more integrated and differentiated EHR governance regimes.