Mechanisms of particulate matter toxicity in neonatal and young adult rat lungs.

Particulate matter (PM*) has been associated with a variety of adverse health effects, primarily involving the cardiovascular and respiratory systems. Researchers continue to investigate biologic mechanisms that may explain how exposure to PM exacerbates or directly causes adverse effects. Particle composition may play a critical role in these effects. In this study we used a diffusion flame system to generate ultrafine iron, soot, and iron combined with soot particles and exposed young adult and neonatal rats to different compositions of these particles. Young adult rats inhaled all three PM compositions on three consecutive days for 6 hours per day. Exposure to soot PM at 250 microg/m3 or to iron PM at 57 microg/m3 demonstrated no adverse respiratory effects. However, we observed mild pulmonary stress when the iron concentration was increased to 90 microg/m3. The most striking effects resulted when the rats inhaled PM composed of iron (45 microg/m3) combined with soot particles (total mass 250 microg/m3). This type of exposure produced significant indicators of oxidative stress, signs of inflammation, and increases in the levels of cytochrome P450 isozymes in the lungs. Repeated three-day exposure of neonatal rats to soot and iron particles in the second and the fourth weeks of life produced significant oxidative stress (elevations in oxidized and reduced glutathione) and ferritin induction. Neonatal rats exposed to PM in the second week of life also had a subtle but significant cell proliferation reduction in the centriacinar regions of the lungs. These findings suggest that iron combined with soot PM can lead to changes in the respiratory tract not found with exposure to iron or soot PM alone at similar concentrations. Unique effects in the neonate suggest that age may play an important role in susceptibility to inhaled particles.

Particle size and composition related to adverse health effects in aged, sensitive rats.

Small increases in concentrations of ambient particulate matter (PM*) have been linked to adverse health effects, especially in older people and people with preexisting respiratory disease. Some epidemiologic studies have shown the association to be stronger with PM less than 2.5 microm in aerodynamic diameter (PM2.5) than with PM less than 10 microm in aerodynamic diameter (PM10). Some scientists and regulators suggest that 2.5 microm might be an arbitrary cutoff and that the effects might be more pronounced for PM less than 0.1 microm in aerodynamic diameter (ultrafine PM). Our first aim was to determine the relation between size of respirable particles and particle toxicity, as well as the health effects of short-term increases (spikes) in particle concentration against backgrounds of relatively low or high baseline exposures. Our second aim was to determine the effect of spikes in concentration of fine particles (0.7 microm in mass median aerodynamic diameter [MMAD]) and ultrafine particles (35 nm in count median diameter [CMD]) of disparate composition: vanadium pentoxide (V2O5) and carbon black. The relative toxicity of these particles was determined in aged rats with mild pulmonary inflammation induced by instilled endotoxin. Our third aim was to determine the influence of age (aged vs young adult) on particle-induced toxicity in these rats.

Fractal geometry of airway remodeling in human asthma.

RATIONALE: Airway wall remodeling is an important aspect of asthma. It has proven difficult to assess quantitatively as it involves changes in several components of the airway wall. OBJECTIVE: To develop a simple method for quantifying the overall severity of airway wall remodeling in asthmatic airways using fractal geometry. METHODS: Negative-pressure silicone rubber casts of lungs were made using autopsy material from three groups: fatal asthma, nonfatal asthma, and nonasthma control. All subjects were lifelong nonsmokers. A fractal dimension was calculated on two-dimensional digital images of each cast. RESULTS: Nonasthma control casts had smooth walls and dichotomous branching patterns with nontapering segments. Asthmatic casts showed many abnormalities, including airway truncation from mucous plugs, longitudinal ridges, and horizontal corrugations corresponding to elastic bundles and smooth muscle hypertrophy, respectively, and surface projections associated with ectatic mucous gland ducts. Fractal dimensions were calculated from digitized images using an information method. The average fractal dimensions of the airways of both the fatal asthma (1.72) and nonfatal asthma (1.76) groups were significantly (p<0.01 and p=0.032, respectively) lower than that of the nonasthma control group (1.83). The lower fractal dimension of asthmatic airways correlated with a decreased overall structural complexity and pathologic severity of disease. CONCLUSION: Fractal analysis is a simple and useful technique for quantifying the chronic structural changes of airway remodeling in asthma.

Airborne particles of the california central valley alter the lungs of healthy adult rats.

Epidemiologic studies have shown that airborne particulate matter (PM) with a mass median aerodynamic diameter < 10 microm (PM10) is associated with an increase in respiratory-related disease. However, there is a growing consensus that particles < 2.5 microm (PM2.5), including many in the ultrafine (< 0.1 microm) size range, may elicit greater adverse effects. PM is a complex mixture of organic and inorganic compounds; however, those components or properties responsible for biologic effects on the respiratory system have yet to be determined. During the fall and winter of 2000-2001, healthy adult Sprague-Dawley rats were exposed in six separate experiments to filtered air or combined fine (PM2.5) and ultrafine portions of ambient PM in Fresno, California, enhanced approximately 20-fold above outdoor levels. The intent of these studies was to determine if concentrated fine/ultrafine fractions of PM are cytotoxic and/or proinflammatory in the lungs of healthy adult rats. Exposures were for 4 hr/day for 3 consecutive days. The mean mass concentration of particles ranged from 190 to 847 microg/m3. PM was enriched primarily with ammonium nitrate, organic and elemental carbon, and metals. Viability of cells recovered by bronchoalveolar lavage (BAL) from rats exposed to concentrated PM was significantly decreased during 4 of 6 weeks, compared with rats exposed to filtered air (p< 0.05). Total numbers of BAL cells were increased during 1 week, and neutrophil numbers were increased during 2 weeks. These observations strongly suggest exposure to enhanced concentrations of ambient fine/ultrafine particles in Fresno is associated with mild, but significant, cellular effects in the lungs of healthy adult rats.

Effects of sarin on temperature and activity of rats as a model for gulf war syndrome neuroregulatory functions.

Coexposure to subclinical levels of nerve gas and to heat stress may have induced some of the clinical symptoms of the Gulf War Syndrome. We tested the hypothesis that single or repeated subclinical exposure to sarin, particularly under conditions of heat stress, would impair regulation of body temperature and locomotor activity. Male F344 rats were housed at 25 degrees C or under mild heat stress at 32 degrees C and were exposed 1 h/day for 1, 5, or 10 days to 0, 0.2, or 0.4 mg/m(3) of sarin in a nose-only exposure system. Body temperature and activity were monitored continuously by telemetry during exposure and 1 month postexposure. Exposed rats showed no clinical symptoms of toxicity such as tremors, despite evidence of reduced red blood cell cholinesterase activity. Heat stress consistently elevated body temperature in unexposed animals, particularly during the dark period when animals are most active. Inhalation of sarin gas at the two subclinical levels did not affect body temperature acutely in a biologically meaningful manner after the first exposure nor after 5 or 10 repeated exposures, either at thermoneutral ambient temperature or during chronic heat stress. There were no consistent effects of sarin or housing temperature on activity. The data suggest that subclinical levels of sarin have minimal effects on temperature regulation and locomotor activity under these observation conditions.

Response of rats to low levels of sarin.

The purpose of this study was to determine whether exposure to levels of sarin causing no overt clinical signs would cause more subtle, adverse health effects that persisted after the exposure ended. Inhalation exposures of male Fischer 344 rats to 0, 0.2, or 0.4 mg/m(3) of sarin for 1 h/day for 1, 5, or 10 days under normal (25 degrees C) and heat-stressed (32 degrees C) conditions were completed and observations were made at 1 day and 1 month after the exposures. The sarin exposures had no observed effects on body weight, respiration rate, and minute volume during exposure nor in body temperature and activity during the 30-day recovery period. There was no evidence of cellular changes in brain determined by routine histopathology nor of any increase in apoptosis. Brain mRNA for interleukin (IL)-1beta, tumor necrosis factor-alpha, and IL-6 was increased in a dose-dependent manner. Autoradiographic studies demonstrated that M1 cholinergic receptor site densities were unchanged at 1 day after repeated exposures with or without heat stress. At 30 days, there was a decrease in M1 receptors in the olfactory tubercle (with and without heat), and, with heat stress, M1 sites also decreased in a dose-dependent manner in the frontal cortex, anterior olfactory nucleus, and hippocampus. M3 receptor sites were not affected by sarin exposure alone. In the presence of heat stress, there was an upregulation in binding site densities in the frontal cortex, olfactory tubercle, anterior nucleus, and striatum immediately after exposure, and these effects persisted at 30 days. Although red blood cell acetylcholinesterase (AChE) was not greatly inhibited by the 1-day exposure, there were 30 and 60% inhibitions after repeated exposures at the low and high doses, respectively. Histochemical staining for AChE demonstrated that sarin exposure alone reduced AChE in the cerebral cortex, striatum, and olfactory bulb. Sarin exposure under heat stress reduced AChE staining in the hippocampus, an area important for memory function. Thus, repeated exposures under heat-stress conditions, to levels of sarin that would not be noticed clinically, resulted in delayed development of brain alterations in cholinergic receptor subtypes that may be associated with memory loss and cognitive dysfunction.

Ozone-induced modulation of airway hyperresponsiveness in guinea pigs.

Although acute exposure to ozone (03*) has been shown to influence the severity and prevalence of airway hyperresponsiveness, information has been lacking on effects due to long-term exposure at relatively low exposure concentrations. The goals of this study were to determine whether long-term repeated ozone exposures could induce nonspecific hyperresponsiveness in normal, nonatopic (nonsensitized) animals, whether such exposure could exacerbate the preexisting hyperresponsive state in atopic (sensitized) animals, or both. The study was also designed to determine whether gender modulated airway responsiveness related to ozone exposure. Airway responsiveness was measured during and after exposure to 0.1 and 0.3 ppm ozone for 4 hours/day, 4 days/week for 24 weeks in normal, nonsensitized guinea pigs, in guinea pigs sensitized to an allergen (ovalbumin) prior to initiation of ozone exposures, and in animals sensitized concurrently with ozone exposures. Both male and female animals were studied. Ozone exposure did not produce airway hyperresponsiveness in nonsensitized animals. Ozone exposure did exacerbate airway hyperresponsiveness to specific and nonspecific bronchoprovocation in both groups of sensitized animals, and this effect persisted at least 4 weeks after the end of the exposures. Although the overall degree of airway responsiveness did differ between genders (males had more responsive airways than did females), the airway response to ozone exposure did not differ between the two groups. Ozone-induced effects upon airway responsiveness were not associated with the number of pulmonary eosinophils or with any chronic pulmonary inflammatory response. Levels of antigen-specific antibodies increased in sensitized animals, and a significant correlation was observed between airway responsiveness and antibody levels. The results of this study provide support for a role of ambient ozone exposure in exacerbation of airway dysfunction in persons with atopy.

Ozone differentially modulates airway responsiveness in atopic versus nonatopic guinea pigs.

While acute exposures to ozone (O(3)) can alter airway responsiveness, effects from long-term exposures at low concentrations are less clear. This study assessed whether such exposures could induce nonspecific hyperresponsiveness in nonatopic (nonsensitized) guinea pigs and/or could exacerbate the pre-existing hyperresponsive state in atopic (sensitized) animals, and whether gender was a factor modulating any effect of O(3). Responsiveness was measured during and following exposures to 0.1 and 0.3 ppm O(3) for 4 h/day, 4 days/wk for 24 wk in male and female nonsensitized animals, those sensitized to allergen (ovalbumin) prior to initiation of O(3) exposures, and those sensitized concurrently with exposures. Ozone did not produce hyperresponsiveness in nonsensitized animals, but did exacerbate hyperresponsiveness to both specific and nonspecific bronchoprovocation challenges in sensitized animals, an effect that persisted through at least 4 wk after exposures ended. Gender was not a factor modulating response to O(3). Induced effects on responsiveness were not associated with numbers of eosinophils in the lungs nor with any chronic pulmonary inflammatory response, but were correlated with antigen-specific antibodies in blood. This study supports a role for chronic O(3) exposure in the exacerbation of airways dysfunction in a certain segment of the general population, namely, those demonstrating atopy.