Alveolar lesions induced by systemic administration of cocaine to rats

In this work, alveolar lesions induced after systemic administration of cocaine (30 mg/kg per day, i.p.) to rats were evaluated both by light microscope analysis for morphological assessment as well as by measurement of the alveolar area as a quantitative index of the alveolar damage. Rats were examined after different times of exposure: 7, 15, 30, 45, 60 and 75 days. The histopathological evaluation of cocaine-treated rats revealed a remarkable thickening in some interalveolar septa, with interstitial hemorrhages, progressive thrombosis and transformation of reticular and elastic fibers into diffuse fibrosis. A significant decrease of the alveolar area was also observed. These findings are indicative of severe changes in capillaries, alveoli and bronchiole after cocaine exposure, which in turn may progressively disrupt the general function of the lungs. Differential mechanisms of systemic toxicity after cocaine exposure are discussed.     

Lung fibrosis in Sprague-Dawley rats, induced by exposure to manual metal arc-stainless steel welding fumes.

To investigate the disease process of pneumoconiosis induced by welding-fume exposure, a lung fibrosis model was established by building a stainless steel arc welding fume generation system and exposing male Sprague-Dawley rats for 90 days. The rats were exposed to welding fumes with concentrations of 57-67 mg/m3 (low dose) and 105-118 mg/m3 (high dose) total suspended particulates for 2 h per day in an inhalation chamber for 90 days. The concentrations of the main metals, Fe, Mn, Cr, and Ni, were measured in the welding fumes, plus the gaseous compounds, including nitrous gases and ozone, were monitored. During the exposure period, the animals were sacrificed after the initial 2-h exposure and after 15, 30, 60, and 90 days. Histopathological examinations were conducted on the animals' upper respiratory tract, including the nasal pathway and conducting airway, plus the gas exchange region, including the alveolar ducts, alveolar sacs, and alveoli. When compared to the control group, the lung weights did not increase significantly in the low-dose group, yet in the high-dose group there was a significant increase from day 15 to day 90. The histopathological examination combined with fibrosis-specific staining (Masson's trichrome) indicated that the lungs in the low-dose group did not exhibit any progressive fibrotic changes. Whereas, the lungs in the high-dose group exhibited early delicate fibrosis from day 15, which progressed into the perivascular and peribronchiolar regions by day 30. Interstitial fibrosis appeared at day 60 and became prominent by day 90, along with the additional appearance of pleural fibrosis. Accordingly, it would appear that a significant dose of welding-fume exposure was required to induce lung fibrosis.     

A comparison of terminal airway remodeling in chronic daily versus episodic ozone exposure

This study compares centriacinar changes by ultrastructural morphology and morphometry following daily versus episodic ozone exposure in rats. Three groups of rats were exposed to air, 0.95 ppm ozone 8 hr daily for 90 days, and 0.95 ppm ozone 8 hr daily in seven successive 5-day episodes separated by 9-day recovery periods for a total of 89 days. Sections from the left lung and dissected acini from the right middle lobe were studied by light and electron microscopy. The centriacinar lesion following episodic exposure was similar but diminished in severity compared to that of rats exposed daily. Damage following episodic exposure appeared to be more than predicted by an exposure regimen which delivered 35% of the total ozone dose during daily exposure. The total volume of affected parenchyma was similar following both exposures. Respiratory bronchiole formation increased following both exposures but this was only statistically significant following daily exposure. The most severe epithelial damage was at the tips of alveolar septa in alveolar ducts distal to the respiratory bronchiole. Interstitial thickness in the injured respiratory bronchiole and proximal alveolar duct increased significantly and similarly following both exposures. Epithelium along the respiratory bronchiole of daily exposed rats was more differentiated. In the episodic group, respiratory bronchiole and alveolar duct epithelium consisted of a range of intermediate, less differentiated bronchiolar or alveolar epithelial cells. The episodic exposure resulted in a diminished lesion, but there appears to be some cumulative effect of repeated exposures with respiratory bronchiolar and alveolar duct epithelium in a more dynamic state of injury and repair.     

Pulmonary response to inhaled Kevlar aramid synthetic fibers in rats

Groups of male rats were exposed to specially prepared ultrafine Kevlar pulp fibers (du Pont's registered trademark for certain aramid fibers) at atmospheric concentrations of either 0.1, 0.5, 3.0, or 18 mg/m3 for 2 weeks. Rats were killed at 0 and 2 weeks and 3 and 6 months postexposure (PE) except the rats exposed to 18 mg/m3, which were killed 0, 4, and 14 days and 1, 3, and 6 months PE. Another group of male rats was exposed to 18 mg/m3 (respirable dust approximately 2.5 mg/m3) of commercial Kevlar fibers for 2 weeks and were killed at 0 and 2 weeks and 3 and 6 months PE. Inhaled ultrafine Kevlar fibers were mostly phagocytized by alveolar macrophages (dust cells) in the alveolar ducts and adjoining alveoli after exposure to either 0.1 or 0.5 micrograms/m3. Most dust cells had disappeared and lungs showed a normal appearance throughout 6 months PE. The pulmonary response almost satisfied the biological criteria for a nuisance dust. Rats exposed to 3 mg/m3 ultrafine Kevlar fibers revealed occasional patchy thickening of alveolar ducts with dust cells and inflammatory cells but with no collagen fibers deposited throughout 6 months PE. After exposure to 18 mg/m3 ultrafine Kevlar, the respiratory bronchioles, alveolar ducts, and adjoining alveoli showed granulomatous lesions with dust cells by 2 weeks PE. The granulomatous lesions converted to patchy fibrotic thickening with dust cells after 1 month PE. The fibrotic lesions were markedly reduced in cellularity, size, and numbers from 3 to 6 months PE but revealed networks of reticulum fibers with slight collagen fiber deposition.     

Comparative cytotoxicity of cadmium and mercury in a human bronchial epithelial cell line (BEAS-2B) and its role in oxidative stress and induction of heat shock protein 70

A number of toxic heavy metals, such as cadmium (Cd) and mercury (Hg), are widely used in occupational settings, and exposure to these metals is associated with the development of pulmonary diseases. Cytotoxicity, apoptosis, and reactive oxygen species (ROS) generation were tested to compare the biological reactivity of these two heavy metals using a human bronchial epithelial cell line, BEAS-2B. Further, heat-shock protein 70 (Hsp70) expression was observed as a sensitive indicator of cellular stress. Exposure to metals (0-50 microM) for 72 h showed more significant cytotoxicity in Cd-treated than Hg-treated cells. Apoptosis was significantly increased in the cells exposed to 50 microM of Cd (3.5-fold) and Hg (3.6-fold). Cd and Hg produced an induction of Hsp70 protein as assayed by Western blotting and enzyme-linked immunosorbent assay (ELISA). Induction of Hsp70 protein by these metals was inhibited by addition of N-acetylcysteine. However, addition of catalase blocked the synthesis of Hsp70 only in Hg-treated cells. Hsp70B and Hsp70C mRNA expression was induced by both metals, while Hsp70A mRNA expression showed no change. Electron spin resonance (ESR) tests showed that hydroxyl radical generation was greater in the reaction of cells with Hg compared to Cd. Intracellular generation of ROS was detected in the cells exposed to both Cd and Hg. These results suggest that both cytotoxicity and apoptosis were significantly elevated with all metals tested; however, Cd was relatively more toxic. Hsp70 protein and mRNA were sensitive to exposure to these metals. Depletion of sulfhydryl groups of cellular proteins and generation of ROS may be involved in metal-induced lung cell damage.     

全氟异丁烯单次暴露诱发小鼠急性肺损伤的长期效应

目的 探讨全氟异丁烯( PFIB)单次暴露诱发急性肺损伤的长期效应.方法 70只雄性小鼠暴露于全氟异丁烯130 mg·m-3 5 min.10只小鼠于暴露后24 h评价肺水肿程度.其余小鼠分别在PFIB暴露后2,4,6,8,12和16周,应用HE染色和天狼星红染色分别观察肺组织的病理变化和胶原沉积,测定肺及血浆中羟脯氨...     

Pattern of deposition of stainless steel welding fume particles inhaled into the respiratory systems of Sprague-Dawley rats exposed to a novel welding fume generating system

In order to investigate occupational diseases related to welding fume exposure, such as nasal septum perforation, pneumoconiosis and manganese intoxication, we built a welding fume exposure system that included a welding fume generator, exposure chamber and fume collector. The fume concentrations in the exposure chamber were monitored every 15 min during a 2-h exposure. Fume (mg/m(3)) concentrations of major metals, including Fe, Mn, Cr, and Ni were found to be consistently maintained. An acute inhalation toxicity study was conducted by exposing male Sprague-Dawley rats to the welding fumes generated in this apparatus by stainless steel arc welding. The rats were exposed in the inhalation chamber to a welding fume with a concentration of 62 mg/m(3) total suspended particulates for 4 h. Animals were sacrificed at 4 h and at 1, 3, 7, 10, and 14 days after exposure. Histopathological examinations were conducted on the animals' upper respiratory tracts, including the nasal pathway and the conducting airway, and on the gas exchange region including the alveolar ducts, alveolar sacs, and alveoli. Diameters of fume particles varied from 0.02 to 0.81 microm and were distributed log normally, with a mean diameter of 0.1 microm and geometric standard deviation of 1.42. Rats exposed to the welding fume for 4 h did not show any significant respiratory system toxicity. The mean particle diameter of 0.1 microm resulted in little adsorption of the welding fume particles in the upper respiratory tract. Particle adsorption took place principally in the lower respiratory tracts, including bronchioles, alveolar ducts, alveolar sacs, and alveoli.     

Pulmonary inflammation and epithelial injury in response to acute ozone exposure in the rat.

To document the time course of the inflammatory response and epithelial injury in the lung following an acute ozone exposure, rats were exposed to 1.0 ppm ozone for periods between 4 and 24 hr. Some of the exposures were followed by postexposure periods in filtered air for up to 20 hr. Bronchoalveolar lavage fluid (BALF) analysis and electron microscopic morphometry on centriacinar regions of lungs fixed by intravascular perfusion were used to assess the degree of pulmonary inflammation and epithelial cell necrosis. Total protein and numbers of neutrophils and epithelial cells in BALF increased as the duration of ozone exposure increased, while BALF macrophages decreased. Quantitation of the neutrophil response in centriacinar lung regions (capillary, interstitial, and epithelial/luminal compartments of the terminal bronchiole and proximal alveolar duct) by morphometry generally correlated with the BALF analysis, and revealed a greater volume per surface area epithelial basal lamina (Vs) of neutrophils in the terminal bronchiole compartments compared to proximal alveoli. Necrosis of epithelial cells in terminal bronchioles, primarily ciliated cells, occurred as early as 4 hr after initiation of ozone exposure, before marked neutrophil migration, and continued during periods of maximal neutrophil influx. We concluded that the early epithelial necrosis in terminal bronchioles during the first few hours of ozone exposure was primarily due to direct ozone toxicity, but could not rule out the possibility of neutrophils contributing to the injury at later time points, especially between 8 and 12 hr of exposure (during periods of maximal neutrophil migration).     

Long-term pulmonary histopathologic changes in rats following acute experimental exposure to chlorine gas

In this study, we aimed to investigate the long-term histopathologic changes in the lungs of rats exposed to a high concentration of chlorine gas. Twenty-four Sprague-Dawley rats were divided into three groups: the control group (group I) (n = 8), early-examined group (group II) (n = 8), and late-examined group (group III) (n = 8). In group II the lungs of rats were taken out just after the exposure, whereas in group III the lungs were taken out 45 days after the exposure. Eosinophilic liquid accumulation in alveoli and bronchi, diffuse intraalveolar edema, vascular congestion, severe perivascular edema, and free bleeding in intraalveolar and interstitial area were observed in the lungs of rats in group II. Interstitial fibrosis and thickening of the alveolar septa were observed in group III. These findings suggest that the people using these cleaning agents are at risk of harming themselves, and the victims of chlorine gas injury should be reexamined at a later period since they may have pulmonary damage even after 45 days of exposure.     

Inhalation toxicity of potassium octatitanate fibers (TISMO) in rats following 13 weeks of aerosol exposure

One hundred and forty male and 140 female rats were divided into 1 control and 3 test groups of 35 rats each, per sex, and exposed by whole-body inhalation to test compound at target concentrations of 0, 1 mg/m(3) (1700 fibers/cm(3), 123 WHO fibers/cm(3)), 10 mg/m(3) (5900 fibers/cm(3), 952 WHO fibers/cm(3)), and 100 mg/m(3) (112,700 fibers/cm(3), 7440 WHO fibers/cm(3)) for 6 h/day, 5 days/wk for 13 wk. Ten rats from each group were killed after 13 wk of exposure and 13 wk of recovery, respectively, for histopathological evaluation. The other 15 rats from each group were killed to study lung clearance after 91 days of exposure, and approximately 1.5 and 3 mo of recovery following the end of the 13 wk of exposure. The mean fiber length of the chamber atmosphere was 2.8, 2.7, and 2.8 microm, while the mean fiber width was 0.48, 0.48, and 0.45 microm for the 1-, 10-, and 100-mg/m(3) chambers, respectively. In the 1-mg/m(3) (123 WHO fibers/cm(3)) exposure group, inhaled particles were mostly retained in a few fiber-laden alveolar macrophages (AMs) within the alveoli adjacent to alveolar ducts without any adverse tissue response throughout 13 wk of exposure and following 13 wk of recovery. This exposure concentration was considered to be a no-observable-adverse-effect level (NOAEL), since the alveoli containing fiber-laden AMs preserved normal structure. After 13 wk of exposure to 10 mg/m(3) (952 WHO fibers/cm(3)), fiber-laden AMs were mainly retained at the alveoli adjacent to the alveolar ducts. Infrequently, slight fibrotic thickening was observed in the alveolar ducts and adjoining alveoli, with proliferating fibroblasts and hyperplastic Type II pneumocytes, and microgranulomas. Occasionally, trace amounts of collagenous material were deposited in the thickened alveolar ducts and adjoining alveolar walls. In addition, minimal alveolar bronchiolarization was occasionally found in the alveoli adjacent to the terminal bronchioles. The peribronchial lymphoid tissue and thymic lymph nodes contained migrated fiber-laden AMs. After 13 wk of recovery, fiber-laden AMs had mostly disappeared from alveoli located in the peripheral acini, but they localized in the alveolar ducts region, suggesting there was active lung clearance of fibers by the AMs via airways. Thickened alveolar ducts and adjacent alveoli were decreased in thickness, a reversible change manifested by reduction of proliferating Type II pneumocytes and fibroblasts. Collagenized fibrosis was slightly more pronounced in the thickened alveolar ducts and adjoining alveoli. The lung response following 13 wk of exposure to 100 mg/m(3) (7440 WHO fibers/cm(3)) and after 13 wk of recovery was similar to those findings of the 952 WHO fibers/cm(3) group but more pronounced, demonstrating a clear concentration-related response. Alveolar ducts and adjoining alveolar walls in the central acini were irregularly thickened with more frequent evidence of minimal collagenized fibrosis. The lung burden and clearance of fibers were estimated by measuring the total content of titanium (Ti) in the lungs, but high variability of Ti content in control and exposed groups prevented meaningful lung clearance analysis.     

Behavioural responses of the supralittoral amphipod Talitrus saltator (Montagu) to trace metals contamination

We investigated behavioural responses (locomotor activity and substrate selection) of the amphipod Talitrus saltator after laboratory exposure to different concentrations of Hg, Cu and Cd. Locomotor activity, measured with a microwave radar device, was assessed in animals exposed to contaminated sand and in sandhoppers previously kept for 48 h in contaminated seawater and tested in clean sand. The contents of Hg, Cu and Cd in T. saltator tissues were measured at the end of pre-exposure to contaminated seawater and after 7 days of exposure to contaminated sand. Substrate selection tests were carried out in a binary choice arena. Tests in contaminated sand showed that sandhopper locomotor activity varied in a dose-dependent manner in the presence of Cu and Hg (at lower Hg concentration they were more active during daytime) but did not show significant changes in Cd-exposed animals except for disappearance of the typical circadian activity pattern. Pre-exposure to trace metals in seawater induced a significant decrease of movements for all metals, although the effects varied according to the toxicity of the metal. Trace metals analyses showed that tissue concentrations of Hg, Cu and Cd were related to their concentrations in the test medium. Substrate selection tests showed avoidance of contaminated sand only when sandhoppers were tested in the presence of both concentrations of Hg and at the higher concentration of Cu. In conclusion, locomotor activity and avoidance behaviour of T. saltator could be used as behavioural biomarkers of trace metals exposure.     

Ozone-induced alterations in collagen metabolism of rat lungs

Rats were exposed to amounts of ozone ranging from 0.5 to 2.0 ppm for intervals of 1, 2, or 3 weeks. Collagen synthesis rates in their lungs were quantitated by biochemical analyses performed with lung minces. Correlative histological observations were made in different lung lobes from the same rats. At all levels of ozone tested, collagen synthesis rates of the lungs were significantly elevated and histologically discernible fibrosis of the alveolar duct walls was observed. Within the range of ozone concentrations studied, the elevation of collagen synthesis rate in exposed rats was a linear function of the level of ozone to which the animals were exposed. We conclude that exposure of rats to near-ambient levels of ozone causes biochemically and histologically discernible fibrotic changes in their lungs, suggesting that such effects may occur at levels of ozone at or near the current ambient air quality standard for this pollutant.     

Long-Term Pulmonary Histopathologic Changes in Rats Following Acute Experimental Exposure to Chlorine Gas

In this study, we aimed to investigate the long-term histopathologic changes in the lungs of rats exposed to a high concentration of chlorine gas. Twenty-four Sprague-Dawley rats were divided into three groups: the control group (group I) (n = 8), early-examined group (group II) (n = 8), and late-examined group (group III) (n = 8). In group II the lungs of rats were taken out just after the exposure, whereas in group III the lungs were taken out 45 days after the exposure. Eosinophilic liquid accumulation in alveoli and bronchi, diffuse intraalveolar edema, vascular congestion, severe perivascular edema, and free bleeding in intraalveolar and interstitial area were observed in the lungs of rats in group II. Interstitial fibrosis and thickening of the alveolar septa were observed in group III. These findings suggest that the people using these cleaning agents are at risk of harming themselves, and the victims of chlorine gas injury should be reexamined at a later period since they may have pulmonary damage even after 45 days of exposure.     

Cumulative rate and distribution of Cd and Pb in the organs of adult male Wistar rats during oral exposure

The degree of accumulation of Cd and Pb in the brains, spleens, lungs, hearts, livers and kidneys of adult Wistar rats was compared both for separate (Cd or Pb) and combined (Cd + Pb) oral exposure. In addition, the metals were administered either with liquids or with solid feed. Rats were exposed to low doses of metals (7 mg Cd and 50 mg Pb/kg feed or L of distilled water) over 6 or 12 weeks. In total the organs of rats accumulated about 0.3–0.5% Cd and 0.4–0.6% Pb supplied with food or drink. The presented studies demonstrated that the distribution of Cd and Pb in the organs is affected by: the type of exposure (separate or combined), the source of metals (feed or drinks) and the duration of exposure. It was found that simultaneous exposure to low doses of Cd and Pb supplied with food is much more hazardous than exposure to such metals supplied with water.     

Prenatal exposure to multiple toxic heavy metals and neonatal neurobehavioral development in Shanghai, China

Background

Epidemiological studies examining the effects of prenatal toxic heavy metals exposure on neonatal development at the population-based level are limited.

Objective

To explore prenatal exposure levels to toxic heavy metals and examine whether exposure is associated with neonatal development.

Methods

A stratified multi-stage cluster sampling methodology was used to investigate 1652 mother-infant pairs from 2008 through 2009 in Shanghai. Cord blood concentrations of Pb, Hg, Cd, As, Tl and NBNA (Neonatal Behavioral Neurological Assessments) were tested. We defined three different exposure levels (low, medium and high) according to the considered safe values.

Results

The median blood Pb, Hg, Cd, As and Tl concentrations were 41 μg/L, 1.88 μg/L, 0.03 μg/L, 0.86 μg/L and 0.02 μg/L, respectively, which all were in the level considered safe. Increasing exposure to Cd, Hg, As and Tl during pregnancy was associated with decreasing NBNA scores. High level-exposure (exceeding the level considered safe) of Hg, Cd and Tl had lower NBNA scores compared to medium and low levels (both in the level considered safe), which implied that the level considered safe of these heavy metals was safe for the newborns' development. The mean decreasing scores of NBNA was 0.61, 1.50 and 0.84 (total score = 40) with high-level exposure of Hg, Cd and Tl, respectively. The medium-level exposure (in the level considered safe) to As had lower NBNA scores compared to low-level exposure, which implied that level of considered safe for As was not safe to the newborns' development. However, prenatal Pb high-exposure did not affect NBNA scores either by single or multiple factor analysis. In addition, important contribution factors for heavy metals pollutants were diet, lifestyle and housing renovation.

Conclusions

Prenatal heavy metals except Pb exposures were associated with NBNA. The adverse effect of medium-level As warrants the need to further investigate the safe range of As.     

Effect of heavy metal exposure on blood haemoglobin concentration and methemoglobin percentage in Lumbricus terrestris

The earthworm haemoglobin (Hb) is a large extracellular hemoprotein flowing in a closed circulatory system. In spite of the fundamental role of this respiratory pigment in earthworm physiology, little is known about its sensitivity to environmental pollutants. The aim of the present work was to investigate the possible effect of heavy metal (cadmium, copper, mercury) exposure on Hb concentration and oxidation state (methemoglobin formation) in the earthworm Lumbricus terrestris. In addition, the tissue concentration of metallothioneins, a well-known biomarker of heavy metal exposure, was determined as an indicator of metal uptake. The animals were exposed to increasing concentrations of Cd, Cu and Hg utilizing the standard acute toxicity test, “Filter paper test” for 48 h. Exposure to heavy metals (10⁻⁵–10⁻³ M for Cd, 10⁻⁴–10⁻³ M for Hg, and 10⁻⁴–10⁻² M for Cu) was found to increase haemoglobin concentration in L. terrestris, although the magnitude of such an increase was dependent on the metal. In addition, metal exposure led to the formation of methemoglobin. Compared to other known biological responses to heavy metals, such as metallothionein induction, methemoglobin increase showed a higher sensitivity and a higher percentage variation in exposed organisms, showing to be a possible suitable biomarker of exposure/effect to be included in a multi biomarker strategy in earthworm in soil monitoring assessment.     

Available intracellular Zn as a potential indicator of heavy metal exposure in rainbow trout hepatocytes

The measurement of available Zn in rainbow trout hepatocytes exposed to a selection of heavy metals was evaluated as a potential end point for assessing heavy metal exposure. Induction of metallothionein, a well-known biomarker for heavy metal exposure, was also evaluated concurrently with available Zn measurements. Rainbow trout hepatocytes were exposed to several concentrations of copper, cadmium, mercury, silver, arsenite, and zinc salts for 48 h at 15°C. Hepatocytes were also exposed to industrial effluent from a metallurgy plant. After the exposure period, hepatocytes were analyzed for metallothionein (MT) and available Zn levels. The results showed that, with divalent metals, available Zn increased with MT levels; there was a significant correlation (R = 0,600; p = 0.0006) between the two. Moreover, the industrial effluent proved to be an inducer of available Zn in hepatocytes, as well as of MT. However, cells exposed to Ag responded with higher levels of available Zn before showing a corresponding MT induction in cells. Inversely, exposure to arsenite led to increased MT without any change in available Zn levels. The value for available Zn tended to be somewhat overestimated in the presence of metals such as Hg, and to a lesser extent Cd. The evaluation of available Zn, in addition to MT, appears to be a valid way of assessing exposure to mono- and divalent metals, though with arsenite, the MT induction response was higher than that of available Zn. The specificity of the available Zn biomarker for heavy metal exposure should be investigated more thoroughly for comparison with the MT biomarker. The measurement of available Zn holds promise as a new biomarker of heavy metal exposure. © 1996 by John Wiley & Sons, Inc.     

The critical role of the cellular thiol homeostasis in cadmium perturbation of the lung extracellular matrix

Cadmium (Cd) inhalation can result in emphysema. Cd exposure of rat lung fibroblasts (RFL6) enhanced levels of metal scavenging thiols, e.g., metallothionein (MT) and glutathione (GSH), and the heavy chain of γ-glutamylcysteine synthetase (γ-GCS), a key enzyme for GSH biosynthesis, concomitant with downregulation of lysyl oxidase (LO), a copper-dependent enzyme for crosslinking collagen and elastin in the extracellular matrix (ECM). Cd downregulation of LO in treated cells was closely accompanied by suppression of synthesis of collagen, a major structure component of the lung ECM. Using rats intratracheally instilled with cadmium chloride (30 μg, once a week) as an animal model, we further demonstrated that although 2-week Cd instillation induced a non-significant change in the lung LO activity and collagen synthesis, 4- and 6-week Cd instillation resulted in a steady decrease in the lung LO and collagen expression. The lung MT and total GSH levels were both upregulated upon the long-term Cd exposure. Emphysematous lesions were generated in lungs of 6-week Cd-dosed rats. Increases of cellular thiols by transfection of cells with MT-II expression vectors or treatment of cells with GSH monoethyl ester, a GSH delivery system, markedly inhibited LO mRNA levels and catalytic activities in the cell model. Thus, Cd upregulation of cellular thiols may be a critical cellular event facilitating downregulation of LO, a potential mechanism for Cd-induced emphysema.     

Pulmonary response of rats exposed to titanium dioxide (TiO2) by inhalation for two years

Rats were exposed to TiO2 by inhalation exposure to concentrations of 0, 10, 50, and 250 mg/m3 for 6 hr/day, 5 days/week for 2 years. There were no abnormal clinical signs, body weight changes, or excess mortality in any exposed group. Exposed groups showed slight increases in the incidence of pneumonia, tracheitis, and rhinitis with squamous metaplasia in the anterior nasal cavity. The pulmonary response at 10 mg/m3 satisfied the biological criteria for a "nuisance dust." The lung reaction was characterized by dust-laden macrophage (dust cell) infiltration in the alveolar ducts and adjoining alveoli with hyperplasia of Type II pneumocytes. Rats at 50 and 250 mg/m3 exposure concentrations revealed a dose-dependent dust cell accumulation, a foamy macrophage response, Type II pneumocyte hyperplasia, alveolar proteinosis, alveolar bronchiolarization, cholesterol granulomas, focal pleurisy, and dust deposition in the tracheobronchial lymph nodes. Minute collagenized fibrosis occurred in the alveolar walls enclosing large dust cell aggregates. The pulmonary lesions with massive dust accumulation appeared to be the result of an overwhelmed lung clearance mechanism at 250 mg/m3 exposure. Bronchioloalveolar adenomas and cystic keratinizing squamous cell carcinomas occurred at 250 mg/m3 exposure, while no compound-related lung tumors were found in rats exposed to either 10 or 50 mg/m3. In addition to excessive dust loading in the lungs of rats exposed chronically at 250 mg/m3, the lung tumors were different from common human lung cancers in terms of tumor type, anatomic location, tumorigenesis, and were devoid of tumor metastasis. Therefore, the biological relevance of these lung tumors and other pulmonary lesions for man is negligible.     

Effects of 28 days silicon dioxide aerosol exposure on respiratory parameters,blood biochemical variables and lung histopathology in rats

Inhalation toxicity of silicon dioxide aerosol (150, 300 mg/m³) daily over a period of 28 days was carried out in rats. The changes in respiratory variables during the period of exposure were monitored using a computer programme that recognizes the modifications of the breathing pattern. Exposure to the aerosol caused a time dependent decrease in tidal volume, with an increase in respiratory frequency compared to the control. Biochemical variables and histopathological observation were noted at 28th day following the start of exposure. Biochemical markers of silica induced lung injury like plasma alkaline phosphatase, lactate dehydrogenase and angiotensine converting enzyme activities increased in a concentration dependent manner compared to control. Increase in the plasma enzymatic activities indicates endothelial lung damage, increased lung membrane permeability. Histopathological observation of the lungs confirmed concentration dependent granulomatous inflammation, fibrosis and proteinacious degeneration. Aggregates of mononuclear cells with entrapped silica particles circumscribed by fibroblast were observed in 300 mg/m³ silica aerosol exposed group at higher magnification. Decrease in tidal volume and increase in respiratory frequency might be due to the thickening of the alveolar wall leading to a decreased alveolar volume and lowered elasticity of the lung tissue. The trends in histological and biochemical data are in conformity with the respiratory data in the present study. This study reports for the first time, the changes in respiratory variables during silica aerosol exposure over a period of 28 days.