Tracheal and bronchoalveolar permeability changes in rats inhaling oxidant atmospheres during rest or exercise

Permeability of tracheal and bronchoalveolar airways of rats was measured and used to examine the effects of inhaled oxidant-containing atmospheres. The atmospheres studied were (a) ozone (O3) at 0.6 ppm (1.2 mg/m3) or 0.8 ppm (1.6 mg/m3); (b) nitrogen dioxide (NO2) at 6 ppm (11.3 mg/m3) or 12 ppm (22.6 mg/m3); (c) O3 + NO2 at 0.6 ppm (1.2 mg/m3) and 2.5 ppm (4.7 mg/m3), respectively; and (d) a 7-component particle and gas mixture (complex atmosphere) representing urban air pollution in a photochemical environment. The rats were exposed for 2 h. The effects of exercise during exposure were evaluated by exposing additional groups in an enclosed treadmill. Exposure of resting rats to 0.8 ppm O3 increased tracheal permeability to DTPA and bronchoalveolar permeability to diethylenetriamine pentaacetate (DTPA) and bovine serum albumin (BSA) at 1 h after the exposure. Bronchoalveolar, but not tracheal, permeability remained elevated at 24 h after the exposure. Exercise during exposure to O3 increased permeability to both tracers in the tracheal and the bronchoalveolar zones, and prolonged the duration of increased permeability in the tracheal zone from 1 h to 24 h, and in the bronchoalveolar zone from 24 h to 48 h. Permeability in the tracheal and bronchoalveolar zones of rats exposed at rest to 6 or 12 ppm NO2 did not differ from controls. However, rats exposed during exercise to 12 ppm NO2 for 2 h developed a significant increase in tracheal and bronchoalveolar permeability to DTPA and BSA at 1 h, but not at 24 or 48 h, after exposure. Exposure at rest to 0.6 ppm O3 plus 2.5 ppm NO2 significantly increased bronchoalveolar permeability at 1 and 24 h after exposure, although exposure at rest to 0.6 ppm O3 alone increased bronchoalveolar permeability only at 1 h after exposure. Exposure to O3 + NO2 during exercise led to significantly greater permeability to DTPA than did exercising exposure to O3 alone. Resting rats exposed to a complex gas/aerosol atmosphere composed of the above O3 and NO2 concentrations, plus 5 ppm (13.1 mg/m3) sulfur dioxide (SO2) and an aerosol of insoluble colloidal Fe2O3 with an aerosol of manganese, ferric, and ammonium salts, demonstrated increased permeability at 1 and 24 h after exposure. Nitric acid vapor was formed in both the O3 + NO2 atmosphere and the complex gas/aerosol atmosphere.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative sensitivity of measurements of lung damage made by bronchoalveolar lavage after short-term exposure of rats to ozone

Consequences of exposure of rats for 2 days or less to O3 at various concentrations between 0.12 and 0.96 ppm were measured using several assays performed on bronchoalveolar lavage fluid. Changes in apparent lung permeability were assessed by measurement of recovery of labelled bovine serum albumin in lung lavage fluid after intravenous injection ("permeability index"). The relative sensitivity of this assay was compared with the sensitivity of measurements of changes in protein and of enzyme content in lavage fluid. Permeability index increased in an exposure concentration-dependent manner after 6 or 24 h of exposure to O3 at or above levels of 0.4 ppm. Permeability index was also increased after 2 days of exposure to 0.2 ppm of O3. The activities of lactate dehydrogenase, acid phosphatase, and N-acetyl-beta-D-glucosaminidase in lung lavage fluid were less sensitive indicators of O3 damage than was altered permeability index. Increased lactate dehydrogenase activity could only be detected after continuous exposure of rats for at least 1 day to 0.64 (or higher) ppm of O3, while acid phosphatase and N-acetyl-beta-D-glucosaminidase activities were increased after exposure of rats to O3 at 0.4 ppm or above for 1 day. Activities of these enzymes were not increased after 6 h of exposure to 0.64 ppm of O3 or after 2 days of exposure to 0.2 ppm. Increased lavage protein content was the most sensitive measurement of the consequences of O3 exposure to rats in these protocols. The lavagable protein content increased after exposure of rats to O3 for 6 h at 0.4 ppm and for 1 or 2 days of exposure to 0.12 ppm, the current peak hourly National Ambient Air Quality standard for O3. While the biological significance of these observations remains to be determined, measurement of lavage protein content is a simple, sensitive indicator of acute changes in the lung caused by exposure to environmentally relevant concentrations of O3.     

Increased serum and urinary concentrations of lung clara cell protein in rats acutely exposed to ozone.

Clara cell protein (CC16) is a 16-17-kDa protein secreted by Clara cells in the bronchial lining fluid of the lung from which it passively diffuses into serum before being eliminated by the kidneys. The concentration of CC16 in serum has recently been proposed as a peripheral marker of the integrity of Clara cells and/or of the bronchoalveolar/blood barrier. To evaluate the sensitivity of this new lung marker to acute epithelial damage induced by ozone (O(3)), CC16 was determined in the serum of rats after a single 3-h exposure to 0.3, 0.6, or 1 ppm O(3). The urinary excretion of the protein was also studied in rats repeatedly exposed to 1 ppm O(3), 3 h/day, for up to 10 days. The concentrations of CC16 in the lung or trachea homogenates, the lung CC16 mRNA levels, and classical markers of lung injury in bronchoalveolar lavage fluid (BALF) were also determined. O(3) produced a transient increase of CC16 concentration in serum that reached values on average 13 times above normal 2 h after exposure to 1 ppm O(3). The intravascular leakage of CC16 was dose-dependent and correlated with the extent of lung injury as assessed by the levels of total protein, LDH, and inflammatory cells in BALF. This effect was most likely responsible for the concomitant marked reduction of CC16 concentrations in BALF and lung homogenate, since the CC16 mRNA levels in the lungs were unchanged and the absolute amounts of CC16 leaking into serum or lost from the respiratory tract were similar. These changes were paralleled by an elevation of the urinary excretion of CC16 resulting from an overloading of the tubular reabsorption process. These results demonstrate that the assay of CC16 in serum and even in urine represents a new noninvasive test to detect the increased lung epithelial permeability induced by O(3).     

Inhalation exposure to sulfur mustard in the guinea pig model: Clinical, biochemical and histopathological characterization of respiratory injuries

Guinea pigs (GP) were exposed (head only) in individual plethysmographs to various concentrations of sulfur mustard vapor, determined online, using FTIR attached to flow chamber. The LCt₅₀ and the inhaled LD₅₀ were calculated at different time points post exposure. Surviving animals were monitored for clinical symptoms, respiratory parameters and body weight changes for up to 30 days. Clinical symptoms were noted at 3 h post exposure, characterized by erythematic and swelling nose with extensive mucous secretion (with or without bleeding). At 6 h post exposure most of the guinea pigs had breathing difficulties, rhonchi and dyspnea and few deaths were noted. These symptoms peaked at 48 h and were noted up to 8 days, associated with few additional deaths. Thereafter, a spontaneous healing was noted, characterized by recovery of respiratory parameters and normal weight gain with almost complete apparent healing within 2 weeks. Histopathological evaluation of lungs and trachea in the surviving GPs at 4 weeks post exposure revealed a dose-dependent residual injury in both lung and trachea expressed by abnormal recovery of the tracheal epithelium concomitant with a dose-dependent increase in cellular volume in the lungs. These abnormal epithelial regeneration and lung remodeling were accompanied with significant changes in protein, LDH, differential cell count and glutathione levels in the bronchoalveolar lavage (BAL). It is suggested that the abnormal epithelial growth and cellular infiltration into the lung as well as the continuous lung inflammation could cause recurrent lung injury similar to that reported for HD exposed human casualties.     

Effect of carbon tetrachloride on hamster tracheal epithelial cells

This study was designed to assess effects of carbon tetrachloride (CCl4) in hamster tracheal epithelium. Adult, male, Syrian golden hamsters were treated with 2.5 ml/kg CCl4 ip, and controls received only the vehicle (peanut oil). Animals were sacrificed after 1, 4, 12, and 24 h. Tissue samples from upper and lower tracheal levels were fixed and embedded in glycol methacrylate for light microscopy. Some tracheal rings were also fixed in formaldehyde/glutaraldehyde cacodylate buffer for transmission electron microscopy. For histopathologic evaluation of the tracheal epithelial cells, each tracheal level was cut transversely at 3 microns and stained with toluidine blue. CCl4 produced injury to ciliated and nonciliated cells in all portions of hamster trachea, although the severity of CCl4-induced injury differed in various levels and regions. The number of damaged cells increased markedly after 1 h in the lower trachea, but not until after 4 h in the upper trachea. By 24 h, the number of injured cells had decreased so that no significant difference from control was evident. The ultrastructural alterations in epithelial cells were obvious as early as 1 h after CCl4 administration. Intracellular organelles, including smooth and rough endoplasmic reticulum, mitochondria, and Golgi apparatuses, were damaged by this chemical. Since CCl4-induced cell injury is dependent on metabolism by intracellular NADPH-dependent cytochrome P450 monooxygenases, these results suggest that hamster tracheal epithelial cells have the potential to activate CCl4 metabolically.     

Acute lung injury from intratracheal exposure to fugitive residual oil fly ash and its constituent metals in normo- and spontaneously hypertensive rats

We have recently shown that the spontaneously hypertensive (SH) rats with underlying cardiovascular disease exhibited greater pulmonary vascular leakage and oxidative stress than healthy normotensive (Wistar Kyoto, WKY) rats after a 3-day inhalation exposure to residual oil fly ash (ROFA) particles (Kodavanti et al., 2000). Since host responsiveness to a 3-day episodic ROFA inhalation could be different from a single acute exposure, we examined ROFA and its constituent metal (vanadium, V; nickel, Ni)-induced lung injury after a single intratracheal (IT) exposure. Male SH and WKY rats (12-13 wk) were IT instilled with either saline or ROFA (0.0, 0.83 or 3.33 mg/kg). The bronchoalveolar lavage fluid (BALF) was analyzed for lung injury markers at 24 and 96 h post-IT. Rats were also IT instilled with 0.0 or 1.5 micromol/kg of either VSO(4) or NiSO(4).6H(2)O in saline (equivalent to a dose of 2-3 mg ROFA), and assessed at 6 and 24 h post-IT. Basal levels of BALF protein, macrophages, and neutrophils, but not lactate dehydrogenase (LDH), were higher in control SH compared to control WKY rats. Lung histology of control SH rats exhibited mild focal alveolitis and perivascular inflammation; these changes were minimal in control WKY rats. ROFA-induced increases in BALF protein, and to a lesser extent in LDH, were greater in SH compared to WKY rats. ROFA IT was associated with the increases in BALF total cells in both strains (SH > WKY). BALF neutrophils increased at 24 h and macrophages at 96 h in a dose-dependent manner (SH > WKY). The increase in BALF neutrophils was largely reversed by 96 h in both rat strains. The V-induced increases in BALF protein and LDH peaked at 6 h post-IT and returned to control by 24 h in WKY rats. In SH rats, BALF protein and LDH were not affected by V. Ni caused BALF protein to increase in both strains at 6 and 24 h; however, the control values at 24 h were high in SH rats, and were not distinguishable from exposed rats. The Ni-induced increase in LDH activity was progressive over a 24-h time period (WKY > SH). The number of macrophages decreased following V and Ni exposure at 6 h, and this decrease was reversed by 24 h in both strains. V caused BALF neutrophils to increase only in WKY rats. The Ni-induced increase in BALF neutrophils was more dramatic and progressive than that of V, but was similar in both strains. Lung histology similarly revealed more severe and persistent edema, perivascular and peribronchiolar inflammation, and hemorrhage in Ni- than in V-exposed rats. This effect of Ni appeared slightly more severe in SH than in WKY rats. In summary, the acute single IT exposure to ROFA resulted in greater pulmonary protein leakage and inflammation in SH rats than in WKY rats. The metallic constituents of ROFA produced these effects in a strain-specific manner such that, at the dose level used, V caused pulmonary injury only in WKY rats, whereas Ni was toxic to both strains.     

EFFECTS OF REPEATED EXPOSURES OF GERIATRIC RATS TO OZONE AND PARTICLE-CONTAINING ATMOSPHERES: AN ANALYSIS OF BRONCHOALVEOLAR LAVAG E AND PLASMA PROTEINS

Inhalation of ozone (O3) and airborne particles less than 10 m (PM-10) in mass median aerodynamic diameter (MMAD) is associated with adverse health effects in sensitive human populations, and pulmonary injury in laboratory animals. In order to simulate environmental exposures of sensitive individuals, such as the elderly, geriatric rats were exposed to O and particulate mixtures. This pilot study determined whether the pul3 monary effects of higher O3 concentrations reported in earlier studies are also seen after repeated exposures to lower O3 concentration used in this study, whether the O3 effects are modified by PM-10 components, and whether plasma biomarkers can be developed as noninvasive tests of pulmonary injury. Male Fischer 344 rats, 22-24 mo old, were exposed 4 h/ day, 3 days/wk for 4 wk to (a) purified air, (b) O3 (0.2 ppm), (c) low-level mixture of carbon (C, 50 g/ m3) plus ammonium bisulfate (ABS, 70 g/m3) plus O3, and (d) high-level mixture of C (100 g/m3) plus ABS (140 g/m3) plus O3. Twenty-four hours after the last exposure, groups of rats were prepared for measurement of protein and albumin concentrations in bronchoalveolar lavage (BAL) as markers of airways permeability, and blood was drawn for analysis of plasma immunoreactive prolyl 4-hydroxylase and fibronectin. Exposures to O3 and O3 /particle mixtures did not produce a consistent, significant change in the BAL markers of permeability. Nonsignificant changes represented individual animal variations. On the other hand, a significant increase in plasma fibronectin was observed in the group exposed to O3, but not in the rats exposed to O3/particle combinations. Such an effect was not observed for plasma immunoreactive prolyl 4- hydroxylase. The inability of low-level O3 and O3/particle combinations to produce intra pulmonary effects suggests potential utility of plasma biomarkers for the evaluation of pulmonary toxicity. These results also suggest modification of O3 effects upon its combination with PM-10.     

Hyperbaric oxygen increases plasma exudation in rat trachea: involvement of nitric oxide

This study investigates the microvascular permeability changes in tracheal tissue of rats exposed to hyperbaric oxygen (HBO). Rats, following exposure to HBO or ambient air (control animals) for 1.5, 3 and 6 h, were prepared for recording of nitric oxide exhaled (FENO) in air using a chemiluminescence analyser. The level of FENO was not statistically different in the two groups. Plasma exudation, evaluated by measuring the leakage of Evans blue (EB) dye into the tracheal tissue, was significantly elevated (48, 86 and 105% at 1.5, 3 and 6 h, respectively) in HBO-treated rats. Plasma exudation in the trachea of control rats was significantly increased (42%, P<0.05) by NG-nitro-L-arginine methyl ester (L-NAME), whereas it was significantly reduced (31%, P<0.05) in rats exposed to HBO for 3 h. N-acetylcysteine (NAC) and flunisolide significantly prevented the increase in plasma leakage in HBO-treated rats. In contrast, indomethacin was devoid of anti-exudative activity in these experiments. Western immunoblot showed a significant increase in the level of inducible nitric oxide synthase (iNOS) protein in the tracheal homogenates of HBO-treated rats, as compared to basal levels. These results indicate that nitric oxide (NO) is involved in the maintenance of microvascular permeability in tracheal tissue of rats. The protective effect observed with the steroid seems to support this hypothesis. Furthermore, the beneficial action of NAC underlines that reactive oxygen species participate in the microvascular permeability changes observed in tracheal tissue of rats exposed to HBO.     

Alteration of epithelial integrity, alkaline phosphatase activity, and fibronectin expression in lungs of rats exposed to ozone.

The deleterious effects of ozone (O3), an oxidant air pollutant, in the lung are dependent on dose and exposure duration and generally evolve with time postexposure. This study characterized the time sequence of epithelial injury and fibronectin expression in the lungs of rats exposed to O3. Bronchoalveolar lavage (BAL) fluid was analyzed for alkaline phosphatase and total protein as markers of epithelial injury and increased permeability, and fibronectin for its role in inflammation and lung injury. The results revealed a time-related increase in total protein in the BAL fluid following a 3-h exposure of rats to 1 ppm O3. The increased protein concentrations peaked at 12 h and then declined, but remained significantly higher than control at 24 h postexposure. A similar time-related significant increase also occurred for BAL fibronectin and alkaline phosphatase activity. However, the return of alkaline phosphatase levels to baseline prior to a comparable reduction in protein levels suggests repair of injured cells, but a delay in the formation of epithelial junctions that limit the transfer of serum proteins to air spaces. By cytochemistry, alkaline phosphatase activity was detected in association with lung type II epithelial cells and in BAL polymorphonuclear leukocytes (PMNs), but not in macrophages. While a significant increase in cytochemically detectable alkaline phosphatase resulted from the increase in PMN number following O3 exposure, mononuclear cells constituted the primary cell type responsible for fibronectin mRNA upregulation. While the cytochemical observations support the role of inflammatory cells in the injury process, the comparability of temporal changes in BAL protein, fibronectin, and alkaline phosphatase suggests a mechanistic role for fibronectin in lung injury.     

Ozone effects on airway responsiveness, lung injury, and inflammation. Comparative rat strain and in vivo/in vitro investigations

Asthmatic individuals appear to be particularly sensitive to the effects of certain air pollutants-including ozone (O(3)), an oxidant ambient air pollutant-for reasons that are poorly understood. The general purpose of these studies, therefore, was to expand and improve upon toxicologic methods for assessing ozone-induced effects on the airways of the rat by (1) developing an in vivo testing procedure that allows detection of airway responsiveness changes in rats exposed to ozone; (2) identifying a strain of rat that may be inherently more sensitive to the effects of ozone; and (3) validation of an in vitro epithelial culture system to more directly assess airway cellular/subcellular effects of ozone. Using methacholine inhalation challenges, we detected increased airway responsiveness in senescent F344 rats acutely after ozone exposure (2 ppm x 2 h). We also determined that acutely after ozone exposure (0.5 ppm x 8 h), Wistar rats developed significantly greater lung injury, neutrophilic inflammation, and bronchoalveolar lavage (BAL) fluid concentrations of IL-6 than either Sprague-Dawley (SD) or F344 rats. SD rats had greater BAL fluid concentrations of prostaglandin E(2) (PGE(2)), while F344 rats consistently exhibited the least effect. Wistar rat-derived tracheal epithelial (RTE) cultures were exposed in vitro to air or ozone (0.1-1.0 ppm x 1 h), and examined for analogous effects. In a concentration-dependent manner, ozone exposure resulted in acute but minor cytotoxicity. RT polymerase chain reaction (PCR) analysis of RNA isolated from ozone-exposed cells demonstrated variable increases in steady-state gene expression of IL-6 at 4 h postexposure, while at 24 h cellular fibronectin expression (EIIIA domain) was decreased. Exposure was without effect on macrophage inflammatory protein 2 (MIP-2) or gamma-glutamyl cysteine synthetase expression. At 6 h postexposure, IL-6 synthesis and apical release appeared increased in ozone-exposed cells (1 ppm x 1 h). MIP-2 release was not significantly increased in ozone-exposed cells. At 2 h postexposure, ozone exposure resulted in minor increases in apical fibronectin, but exposure was without effect on basolateral accumulation of fibronectin. Exposure to 1.0, but not 0.1 ppm (x 1 h), increased production of cyclooxygenase (i.e., PGE(2)) and noncyclooxygenase products of arachidonic acid. Results demonstrate that multiple inflammatory mediator pathways are affected by ozone exposure. Such effects could exacerbate morbidity in individuals with preexisting airway inflammation such as asthmatics.     

Adverse respiratory effects in rats following inhalation exposure to ammonia: respiratory dynamics and histopathology

Acute respiratory dynamics and histopathology of the lungs and trachea following inhaled exposure to ammonia were investigated. Respiratory dynamic parameters were collected from male Sprague–Dawley rats (300–350?g) during (20?min) and 24?h (10?min) after inhalation exposure for 20?min to 9000, 20,000, and 23,000?ppm of ammonia in a head-only exposure system. Body weight loss, analysis of blood cells, and lungs and trachea histopathology were assessed 1, 3, and 24?h following inhalation exposure to 20,000?ppm of ammonia. Prominent decreases in minute volume (MV) and tidal volume (TV) were observed during and 24?h post-exposure in all ammonia-exposed animals. Inspiratory time (IT) and expiratory time (ET) followed similar patterns and decreased significantly during the exposure and then increased at 24?h post-exposure in all ammonia-exposed animals in comparison to air-exposed controls. Peak inspiratory (PIF) and expiratory flow (PEF) significantly decreased during the exposure to all ammonia doses, while at 24?h post-exposure they remained significantly decreased following exposure to 20,000 and 23,000?ppm. Exposure to 20,000?ppm of ammonia resulted in body weight loss at 1 and 3?h post-exposure; weight loss was significant at 24?h compared to controls. Exposure to 20,000?ppm of ammonia for 20?min resulted in increases in the total blood cell counts of white blood cells, neutrophils, and platelets at 1, 3, and 24?h post-exposure. Histopathologic evaluation of the lungs and trachea tissue of animals exposed to 20,000?ppm of ammonia at 1, 3, and 24?h post-exposure revealed various morphological changes, including alveolar, bronchial, and tracheal edema, epithelial necrosis, and exudate consisting of fibrin, hemorrhage, and inflammatory cells. The various alterations in respiratory dynamics and damage to the respiratory system observed in this study further emphasize ammonia-induced respiratory toxicity and the relevance of efficacious medical countermeasure strategies.     

Repeated challenge with dinitrobenzene sulphonic acid in dinitrofluorobenzene-sensitized mice results in vascular hyperpermeability in the trachea: a role for tachykinins.

1. This study investigates the role of tachykinins in a repeated challenge with dinitrobenzene sulphonic acid (DNS) on the tracheal vascular permeability in dinitrofluorobenzene (DNFB)-sensitized mice. 2. DNFB-contact sensitization was followed by an intranasal (i.n.) challenge with DNS. A second challenge with DNS was administered 24 h after the first challenge. To assess changes in tracheal vascular permeability, Evans blue dye accumulation in tracheal tissue was measured. 3. A repeated challenge with DNS in DNFB-sensitized mice led to a 2.8 fold increase in tracheal vascular permeability when compared to DNFB-sensitized and vehicle-challenged mice or a 2.5 fold increase when compared to DNFB-sensitized single DNS-challenged mice (P<0.001, ANOVA). 4. RP67580 (10-9 mol mouse-1 i.v.) reduced the increased tracheal vascular permeability induced by a second exposure to DNS in DNFB-sensitized mice completely when injected 15 min before the second challenge (P<0.001, ANOVA). 5. The increased tracheal vascular permeability response induced by the second exposure to DNS could be mimicked with i.n. application of capsaicin (10-10 mol mouse-1) or substance P (SP) (10-12 mol mouse-1) to DNFB-sensitized and single DNS-challenged mice. 6. These results suggest that both tachykinin NK1 receptors and sensory nerves are involved in the development of vascular hyperpermeability changes found in the trachea of DNFB-sensitized mice after a repeated DNS-challenge.     

Amelioration of ozone-induced lung injury by anti-tumor necrosis factor-alpha.

Ozone (O(3)) is a significant component of atmospheric air pollution and produces detrimental effects in the lung. Although the mechanism of O(3)-induced lung inflammation and injury is unclear, the increased release of the proinflammatory cytokine tumor necrosis factor-alpha (TNF-alpha) by lung cells following O(3) exposure may shed some light on this subject. To investigate the role of TNF-alpha in the O(3)-induced pulmonary insult, we intraperitoneally injected rats with either rabbit preimmune serum or rabbit antirat TNF-alpha 1 h prior to O(3) exposure. Approximately 12 h after the end of O(3) exposure the animals were sacrificed, the lungs lavaged, and tissue samples collected for expression of cytokine genes relevant to inflammation. The bronchoalveolar lavage fluid (BALF) was analyzed for albumin as a marker of pulmonary epithelial permeability changes and for fibronectin for its role in lung injury and repair. The lavage cells were collected, counted, and identified to quantitate the inflammatory response. Ozone exposure resulted in a significant increase in BALF albumin and fibronectin as compared to air-exposed controls and a significant increase in BALF polymorphonuclear leukocytes (PMNs). Antibody treatment produced a significant decrease in BALF albumin and PMNs as compared to O(3)-exposed rats given preimmune serum. Antibody treatment did not affect the BALF fibronectin concentration or the total cell count in the BAL. Tissue analysis for gene arrays revealed an activation of IL-1alpha, IL-6, and IL-10 in animals exposed to O(3). The gene expression was downregulated in animals treated with anti-TNF-alpha antibody prior to O(3) exposure. The results suggest a central role for TNF-alpha in the mechanistic pathways critical to lung inflammation. The significance of TNF-alpha in the inflammation and epithelial injury produced by ozone exposure reflects its overall contribution through modulation of other cytokines.     

Biological responses in rats exposed to cigarette smoke and Middle East sand (dust)

Respiratory symptoms are frequently reported in personnel deployed to the Middle East. This project characterized the respiratory toxicity of inhaled Iraqi sand (IS). Adult rats underwent a 6-wk inhalation to air or mainstream cigarette smoke (MSCS) (3?h/d, 5?d/wk) that included exposure to IS or crystalline silica (1?mg/m(3), 19?h/d, 7?d/wk) or air during the last 2 weeks. Assessments included motor activity, whole-body plethysmography, cytological and biochemical analysis of bronchoalveolar lavage fluid, lung metal burden, nasal and lung pathology, and changes in lung protein and gene expression. A number of metals including nickel, manganese, vanadium, and chromium were detected in IS. Elevated lung parenchyma aluminum, silica, barium, manganese, and vanadium concentrations were seen in IS-exposed rats, suggesting that several metals present in IS are bioavailable. Rats exposed to IS only developed mild inflammation in the anterior nose and lung. Silica inhalation was associated with some pulmonary responses that were not seen in IS-exposed rats, such as mild laryngeal and tracheal inflammation, mild tracheal epithelial hyperplasia, and elevated lung silica concentrations. MSCS inhalation with or without co-exposure to either IS or silica resulted in changes consistent with pulmonary inflammation and stress response. Rats exposed to MSCS and silica had more widespread airway lesions when compared with rats exposed to MSCS only. Silica-exposed rats had more robust pulmonary gene expression and proteomic responses than that seen in IS-exposed rat. Our studies show that the respiratory toxicity of IS is qualitatively similar to or less than that seen following short-term silica exposure.     

ALTERATION OF EPITHELIAL INTEGRITY,ALKALINE PHOSPHATASE ACTIVITY,AND FIBRONECTIN EXPRESSION IN LUNGS OF RATS EXPOSED TO OZONE

The deleterious effects of ozone (O3), an oxidant air pollutant, in the lung are dependent on dose and exposure duration and generally evolve with time postexposure. This study characterized the time sequence of epithelial injury and fibronectin expression in the lungs of rats exposed to O3. Bronchoalveolar lavage (BAL) fluid was analyzed for alkaline phosphatase and total protein as markers of epithelial injury and increased permeability, and fibronectin for its role in inflammation and lung injury. The results revealed a time-related increase in total protein in the BAL fluid following a 3-h exposure of rats to 1 ppm O3. The increased protein concentrations peaked at 12 h and then declined, but remained significantly higher than control at 24 h postexposure. A similar time-related significant increase also occurred for BAL fibronectin and alkaline phosphatase activity. However, the return of alkaline phosphatase levels to baseline prior to a comparable reduction in protein levels suggests repair of injured cells, but a delay in the formation of epithelial junctions that limit the transfer of serum proteins to air spaces. By cytochemistry, alkaline phosphatase activity was detected in association with lung type II epithelial cells and in BAL polymorphonuclear leukocytes (PMNs), but not in macrophages. While a significant increase in cytochemically detectable alkaline phosphatase resulted from the increase in PMN number following O3 exposure, mononuclear cells constituted the primary cell type responsible for fibronectin mRNA upregulation. While the cytochemical observations support the role of inflammatory cells in the injury process, the comparability of temporal changes in BAL protein, fibronectin, and alkaline phosphatase suggests a mechanistic role for fibronectin in lung injury.     

Lung responses to hypothyroidism, hyperthyroidism, and lipopolysaccharide challenge in rats

The objectives of this investigation were to study the effects of hypo- and hyperthyroidism on some factors involved in lung injury under basal conditions (air exposure) and during an inflammatory response induced by inhalation exposure to lipopolysaccharide (LPS; 100 microg/ml; 3 h) in adult rats. Thyroid status was altered by thyroidectomy or thyroxine injections for 15 d. Hyperthyroidism alone caused a greater degree of lung cell damage, an increase in the permeability of the alveolar-capillary barrier, a rise in the total number of phagocytic cells obtained by bronchoalveolar lavage (BAL), and enhanced nitric oxide (NO) release by phagocytic cells relative to that in euthyroid control animals. Hypothyroidism alone was associated with opposite effects. Exposure of animals to LPS produced inflammatory responses, which included significant increases in lung cell damage, permeability of the alveolar-capillary barrier, number of phagocytic cells obtained by BAL, and NO production by the phagocytic cells. In general, hyperthyroidism enhanced the effects of LPS, while hypothyroidism reduced LPS-induced responses. These results suggest that thyroid status alone can affect some of the factors involved in lung injury and also modulate some of the inflammatory effects of LPS. Hyperthyroidism tends to enhance lung injury, while hypothyroidism seems to reduce lung injury.     

Proliferation of lung and airway cells induced by nitrogen dioxide

Proliferation of lung cells of Chinese hamsters was examined in several regions of the lung parenchyma and ciliated airway epithelium after a 24-h exposure to 28.2 mg/m3 (15 ppm) nitrogen dioxide (NO2). Label was retained 3 wk after the injection of [3H]thymidine, and autoradiographic methods were used to localize the site of retention. By 24 h after administration of [3H]thymidine, parenchymal areas, exclusive of airways, showed an increased labeling index, indicative of cell death and replacement. This increase in the number of labeled cells persisted for 3 wk. Type II cells were labeled twice as frequently in regions of the terminal bronchiole than in other alveolar areas. Type II cell cycle time was reduced from 26 to 3 d after NO2 exposure. Alveolar macrophages were significantly labeled in the alveolar areas during the thymidine pulse at the end of the exposure episode and retained label for 3 wk. Airway epithelia showed no labeling in the trachea and progressively greater labeling in increasingly small er airways. Epithelial cells lining the small airways and alveoli showed greater susceptibility to NO2 injury than cells lining the bronchi or trachea. Nonciliated or basal cells serve as a precursor of ciliated cells in the epithelium of small airways (0.35 mm) and bronchi.     

Ozone-induced lung inflammation and mucosal barrier disruption: toxicology, mechanisms, and implications

The airway epithelial lining serves as an efficient barrier against penetration of exogenous particles and macromolecules. Disruption of this barrier following O3 exposure represents a state of compromised epithelial defenses leading to increased transmucosal permeability. Although the barrier disruption following an acute exposure is transient in nature, the brief period of disruption caused by O3, an oxidant air pollutant, provides an opportunity for facilitated entry of a potentially toxic particulate copollutant(s) across the airway epithelia. The subsequent deposition and retention of the copollutant(s) in the subepithelial compartment for prolonged periods adds the risk of injury due to chronic exposure following an acute episode. Toxicological studies from several laboratories have demonstrated alterations in epithelial permeability, suggestive of barrier disruption, in animals and humans exposed to O3. Inflammatory cells represent another important component of pulmonary defenses, but upon activation these cells can both induce and sustain injury. The recruitment of these cells into the lung following O3 exposure presents a risk of tissue damage through the release of toxic mediators by activated inflammatory cells. Several studies have reported concomitant changes in permeability and recruitment of the inflammatory cells in the lung following O3 exposure. In these studies, an inflammatory response, as detected by an increase in the number of polymorphonuclear leukocytes in the bronchoalveolar lavage (BAL) or in lung parenchyma, was accompanied by either an increased tracer transport across the airway mucosa or an elevation in the levels of total protein and/or albumin in the BAL. The magnitude of response and the time at which the permeability changes and inflammatory response peaked varied with O3 concentration, exposure duration, and the mode of analysis. The responsiveness to O3 also appeared to vary with the animal species, and increased under certain conditions such as physical activity and pregnancy. Some of the effects seen after an acute exposure to O3 were modified upon repeated exposures. The responses following repeated exposures included attenuation, persistence, or elevation of permeability and inflammation. Mechanistic studies implicate chemotactic factors, cellular mediators, and cell-surface-associated molecules in the induction of inflammation and lung injury. In discussing these studies, this review serves to introduce the mucosal barrier functions in the lung, evaluates inflammatory and permeability consequences of O3, addresses mechanisms of inflammatory reactions, and offers alternate viewpoints.     

Distribution, retention, and elimination of pyrene in rats after inhalation

Pyrene was measured in tissues of Fischer 344 rats are various times after inhalation of pyrene aerosols (500 microgram/l; mass median diameter, 0.3-0., micrometer) for 1 h. Significant quantities of pyrene were found in nasal turbinates, trachea, lungs, kidney, and liver immediately after exposure. Clearance from the respiratory tract was rapid; concentrations in the trachea and lungs 48 h after exposure were 20 and 5% of the concentrations present 1/2 h after exposure. Pyrene also cleared from liver and kidney at a relatively rapid rate; concentrations in these tissues 48 h after exposure were approximately 10% of those 1/2 h after exposure. Concentrations in the gastrointestinal tract 24 h after exposure were 4 times those found 1/2 h after exposure. Pyrene cleared from the gastrointestinal tract approximately 4 d after exposure. Thus, inhaled pyrene is rapidly cleared from the respiratory tract by mucocilliary action from the trachea and bronchi and by translocation from the respiratory tract to the liver and kidney; it is eliminated primarily through the gastrointestinal tract.     

In vivo hydroquinone exposure impairs allergic lung inflammation in rats

Hydroquinone (HQ) is naturally found in the diet, drugs, as an environmental contaminant and endogenously generated after benzene exposure. Considering that HQ alters the immune system and its several source of exposures in the environment, we hypothesized that prolonged exposure of HQ could affect the course of an immune-mediated inflammatory response. For this purpose, male Wistar rats were intraperitoneally exposed to vehicle or HQ once a day, for 22 days with a 2-day interval every 5 days. On day 10 after exposure with vehicle or HQ, animals were ovalbumin (OA)-sensitized and OA-aerosolized challenged on day 23. HQ exposure did not alter the number of circulating leukocytes but impaired allergic inflammation, evidenced by lower number of leukocytes in the bronchoalveolar lavage fluid 24h after OA-challenge. Reduced force contraction of ex vivo tracheal segments upon OA-challenge and impaired mesentery mast cell degranulation after in situ OA-challenge were also detected in tissues from HQ exposed animals. The OA-specificity on the decreased responses was corroborated by normal trachea contraction and mast cell degranulation in response to compound 48/80. In fact, lower levels of circulating OA-anaphylactic antibodies were found in HQ exposed rats, as assessed by passive cutaneous anaphylaxis assay. The reduced level of OA-anaphylactic antibody was not dependent on lower number or proliferation of lymphocytes. Nevertheless, lower expression of the co-stimulatory molecules CD6 and CD45R on OA-activated lymphocytes from HQ exposed rats indicate the interference of HQ exposure with signaling of the humoral response during allergic inflammation. Together, these data indicate specific effects of HQ exposure manifested during an immune host defense.