Retention of nickel oxide (green) aerosol in rat lungs by long-term inhalation

Wistar male rats were exposed to green nickel oxide [NiO(G)] aerosols (mass median aerodynamic diameter, 0.6 μm) for 7 h/d, 5 d/wk for up to 12 mo. The average exposure concentration was controlled at 0.3 mg/m³ and 1.2 mg/m³ during the exposure period. Some rats were sacrificed just after the 3- and 6-mo exposures, and others were sacrificed after the termination of the 12-mo exposure. There were no differences in body weight gain between NiO(G) exposure groups and controls. The lung weights in the exposed rats were heavier than those in the control ones. Nickel concentrations in lungs of exposure groups were much higher than those of controls. The nickel concentrations in liver, kidney, spleen, and blood slightly increased with the passing of the exposure time. The nickel content in rat lungs during the 12-mo exposure was estimated theoretically. The estimated values agreed with the experimental data. This result shows that the clearance rate increases with the decreasing of the particle diameter.     

Comparative deposition and clearance of various nickel compounds exposed by inhalation in rats

Wistar male rats were exposed to three types of nickel compounds, NiO(G), NiO(B), and Ni₃S₂, for 6 h/d, 5 d/wk for 6 mo. The solubility of these chemicals to saline solution was 0.3 ppm for NiO(G), 3.5 ppm for NiO(B), and 310 ppm for Ni₃S₂. Controls were exposed to clean air under similar conditions. Some rats were sacrificed 24 h after the termination of the final repeated exposure, and the remaining rats were kept for a 12-mo clearance period before sacrifice. There was no significant difference in body weight between exposed rats and controls and also no significant differences in organs weights, except for lungs in the case of Ni₃S₂, between exposed rats and controls. Nickel concentration in the lungs just after the exposure to nickel compounds was the highest when compared to other organs. The apparent deposition fractions (%) in the lungs were 0.5 ± 0.1 for NiO(G), 1.0 ± 0.3 for NiO(B), and 0.5 ± 0.1 for Ni₃S₂., After the clearance period, there were no significant differences in organ weights, except for the lungs in case of Ni₃S₂, between the exposed rats and the controls. During the 12 mo of clearance, 82% of deposited NiO(G), 73% of NiO(B), and 98% of Ni₃S₂ were cleared from lungs.     

Biological half time of deposited nickel oxide aerosol in rat lung by inhalation

Wistar male rats were exposed to nickel oxide (NiO) aerosols (mass median aerodynamic diameter, 1.2 and 4.0 μm). The average exposure concentration was controlled from a low level of 0.6 mg/m³ to a high level of 70 mg/m³ and total exposure time was 140 h. Some rats were sacrificed just after the exposure, whereas others were exposed for 1 mo and kept for 12 and 20 mo clearance periods before sacrifice. There were no differences in body weight gain between NiO exposure groups and controls. Nickel concentrations in lungs of exposure groups were much higher than those of controls and decreased with the passing of the clearance time. No apparent deposition of nickel was observed in the liver, kidney, spleen, and blood immediately after the exposure, but in the case of the high exposure groups, the nickel concentration in the liver, spleen, and blood slightly increased with the increasing time of clearance. The biological half time of NiO deposited in the lungs was estimated by the assumption that the amount of the clearance is proportional to the amount of the NiO deposited. This resulted in a biological half time of 11.5 and 21 mo for 1.2 and 4.0 μm, respectively.     

Essential trace metals and specific organ weights in diet-restricted and ad lib-fed rats

Wistar male rats were exposed to nickel oxide (NiO) aerosols (mass median aerodynamic diameter, 1.2 μm). The average exposure concentration was controlled from low level (0.6 mg/m³) to high level (8.0 mg/m³) and total exposure time ranged from 140 to 216 h. Some rats were sacrificed just after the exposure, whereas others were exposed for 1 mo and kept for a 1-yr clearance period before sacrifice. There were no differences in body weight gain between NiO exposure groups and controls. Nickel concentrations in lungs of exposure groups were much higher than those of controls. No apparent deposition of nickel was observed in liver, kidney, spleen, heart, brain, and blood, but lung burdens of up to about 2.35 mg of NiO were found. The apparent deposition fractions were 19.8 and 14.5% after the exposure to average concentrations of 1.4 and 6.5–7.0 mg/m³, respectively. The clearance rate of NiO deposited in lungs may be small.     

Biological half-time in rats exposed to nickel monosulfide (amorphous) aerosol by inhalation

This study reports the biological half-time of amorphous nickel monosulfide(NiS(A)) aerosol retained in rat lungs. Wistar male rats were exposed to NiS(A) aerosols (mass median aerodynamic diameter: 4.0 μm) for a single 4 h exposure, or for 7 h/d, 5 d/wk for 1 mo. The average exposure concentrations were controlled at 107 mg/m³ for the single exposure and at 8.8 mg/m³ for the repeated exposures by a dust generator consisting of a continuous fluidized bed with an overflow pipe and a screw feeder. After the exposures, the nickel contents in the rat organs, blood, and urine were measured and histopathological examinations were performed. The biological half time of NiS(A) in rat lungs was 20 h, which was extremely shorter than 21 mo of green nickel oxide (NiO(G)). There were no malignant tumors in any of the exposure groups.     

Effects of nickel oxide on the production of tumor necrosis factor by alveolar macrophages of rats

To evaluate the effect of green nickel oxide (NiO) on the production of tumor necrosis factor (TNF) by alveolar macrophages, alveolar macrophages were exposed to NiO in vitro and in vivo. For the in vitro study, rats alveolar macrophages were incubated with NiO on a microplate for 24 h. TNF activity in the culture supernatant was determined by the L929 bioassay. Rats alveolar macrophages cultured with 100 and 200 μg/mL of NiO in vitro induced the production of TNF, however, it was not statistically significant compared with the control that was free from NiO exposure. For exposure in vivo, rats were divided into two groups. Five were exposed to a daily concentration of 11.7±2.0 mg/m³ of NiO for an 8-hr/d, 5 d/wk, for 4 wk, and five rats (control) were kept in a cage and not exposed to NiO. Bronchoalveolar lavage was performed and the recovered alveolar macrophages were incubated on a microplate for 24 h. TNF production by exposed alveolar macrophages was significantly higher than that of controls.     

Electron microscopical findings with special reference to cancer in rats caused by inhalation of nickel oxide

A special exposure system was used for the inhalation of nickel oxide (NiO) aerosol by Wistar male rats. The median aerodynamic diameter and the geometric standard deviation were 1.2 μm and 2.2, respectively. A histopathological study of the rats was performed immediately, and at intervals of 12 and 20 mo after a 1-mo expsoure to NiO. Electron microscopy showed that localization of NiO particles was restricted to the lungs and that each particle had been engulfed by the alveolar macrophages. Type II pneumocytes and nonciliated bronchiolar epithelial cells (Clara cells), as well as numerous tubular myelin (surfactant) in the alveoli were prominent. In rats dissected after 12 mo, clusters of NiO particles were still present within the terminal bronchioli, alveolar walls, and lysosomes of the alveolar macrophages. Pools of tubular myelin were observed in the peribron-chial lymphatics. The Clara cells, which project into the lumen of bronchioli, showed active secretion and were filled with smooth en-doplasmic reticulum (SER) in the apical cytoplasm. In the experimental group sacrificed after 20 mo, one rat had papillary adenocarcinoma and two rats showed adenomatosis in the peripheral portion of the lung, but none in the upper respiratory tract.     

Oxidative DNA damage in cultured cells and rat lungs by carcinogenic nickel compounds.

DNA damage in cultured cells and in lungs of rats induced by nickel compounds was investigated to clarify the mechanism of nickel carcinogenesis. DNA strand breaks in cultured cells exposed to nickel compounds were measured by using a pulsed field gel electrophoresis technique. Among nickel compounds (Ni(3)S(2), NiO (black), NiO (green), and NiSO(4)), only Ni(3)S(2), which is highly carcinogenic, induced lesions of both double- and single-stranded DNA in cultured human cells (Raji and HeLa cells). Treatment of cultured HeLa cells with Ni(3)S(2) (10 microg/ml) induced a 1.5-fold increase in 8-hydroxy-2'-deoxyguanosine (8-OH-dG) compared with control, whereas NiO (black), NiO (green), and NiSO(4) did not enhance the generation of 8-OH-dG. Intratracheal instillation of Ni(3)S(2), NiO(black), and NiO(green) to Wistar rats increased 8-OH-dG in the lungs significantly. NiSO(4) induced a smaller but significant increase in 8-OH-dG. Histological studies showed that all the nickel compounds used induced inflammation in lungs of the rats. Nitric oxide (NO) generation in phagocytic cells induced by Ni(3)S(2), NiO(black), and NiO(green) was examined using macrophage cell line RAW 264.7 cells. NO generation in RAW 264.7 cells stimulated with lipopolysaccharide was enhanced by all nickel particles. Two mechanisms for nickel-induced oxidative DNA damage have been proposed as follows: all the nickel compounds used induced indirect damage through inflammation, and Ni(3)S(2) also showed direct oxidative DNA damage through H(2)O(2) formation. This double action may explain relatively high carcinogenic risk of Ni(3)S(2).     

Isoproterenol improves ability of lung to clear edema in rats exposed to hyperoxia.

Exposure of adult rats to 100% O(2) results in lung injury and decreases active sodium transport and lung edema clearance. It has been reported that beta-adrenergic agonists increase lung edema clearance in normal rat lungs by upregulating alveolar epithelial Na(+)-K(+)-ATPase function. This study was designed to examine whether isoproterenol (Iso) affects lung edema clearance in rats exposed to 100% O(2) for 64 h. Active Na(+) transport and lung edema clearance decreased by approximately 44% in rats exposed to acute hyperoxia. Iso (10(-6) M) increased the ability of the lung to clear edema in room-air-breathing rats (from 0.50 +/- 0.02 to 0.99 +/- 0. 05 ml/h) and in rats exposed to 100% O(2) (from 0.28 +/- 0.03 to 0. 86 +/- 0.09 ml/h; P < 0.001). Disruption of intracellular microtubular transport of ion-transporting proteins by colchicine (0. 25 mg/100 g body wt) inhibited the stimulatory effects of Iso in hyperoxia-injured rat lungs, whereas the isomer beta-lumicolchicine, which does not affect microtubular transport, did not inhibit active Na(+) transport stimulated by Iso. Accordingly, Iso restored the lung's ability to clear edema after hyperoxic lung injury, probably by stimulation of the recruitment of ion-transporting proteins (Na(+)-K(+)-ATPase) from intracellular pools to the plasma membrane in rat alveolar epithelium.     

The influence of maternal nicotine exposure on neonatal lung carbohydrate metabolism.

The influence of maternal nicotine exposure (1 mg/kg body mass/day) during pregnancy and lactation on energy metabolism of lung tissue of neonatal rats were investigated. The glucose turnover of the lung tissue of the neonatal rats exposed to nicotine via the placenta and mother's milk was 86.4% higher than that of the controls. Glycolysis was however suppressed by 22.7% (P < 0.01). The adenine nucleotide pool (ATP+ADP+AMP) was 32.8% higher for the lungs of the 3 week old neonates exposed to nicotine than that of the control rat lung. After 4 weeks of nicotine withdrawal glycolysis of those animals exposed to nicotine were still inhibited to the same extent than during exposure. The adenine nucleotide pool was 69.95% higher than that of the controls. It is proposed that the inhibition of glycolysis was due to the high ATP/ADP ratio of the lungs of the nicotine exposed rats.     

Distribution of various nickel compounds in rat organs after oral administration

In this study, eight kinds of nickel (Ni) compounds were orally administered to Wistar male rats and the distribution of each compound was investigated 24 h after the administration. The Ni compounds used in this experiment were nickel metal [Ni−M], nickel oxide (green) [NiO(G)], nickel oxide (black) [NiO(B)], nickel subsulfide [Ni₃S₂], nickel sulfide [NiS], nickel sulfate [NiSO₄], nickel chloride [NiCl₂], and nickel nitrate [Ni(NO₃)₂]. The solubilities of the nickel compounds in saline solution were in the following order; [Ni(NO₃)₂>NiCl₂>NiSO₄]≫[NiS>Ni₃S₂]>[NiO(B)>Ni−M>NiO(G)]. The Ni level in the visceral organs was higher in the rats given soluble Ni compounds; Ni(NO₃)₂, NiCl₂, NiSO₄, than that in the rats receiving other compounds. In the rats to which soluble Ni compounds were administered, 80–90% of the recovered Ni amounts in the examined organs was detected in the kidneys. On the other hand, the Ni concentration in organs administered scarcely soluble Ni compounds; NiO(B), NiO(G), and Ni−M were very low. The estimated absorbed fraction of each Ni compounds was increased with the increase of the solubility. These results suggest that the kinetic behavior of Ni compounds administered orally is closely related with the solubility of Ni compounds, and that the solubility of Ni compounds is one of the important factors for determining the health effect of Ni compounds.     

Hormonal and organ weight changes in rats exposed to simultaneous chronic effects of CO and NO2

Activity of the pituitary-adrenocortical, sympathico-adrenomedullary and thyroid gland systems was examined in groups of male adult rats, average weight 180 g, exposed for 2 months to a mixture of 7 mg.m-3 NO2 and 32 mg.m-3 CO in air and in groups of matched controls inhaling fresh air. Corticosterone (B) concentrations in the serum of rats were determined by the competitive protein-binding method, noradrenaline (NA) in the hypothalamus and catecholamines (CA) in suprarenals by fluorometry, thyroxine (T4) and triiodothyronine (T3) in the thyroid gland by the RIA technique. Measurements of organ weight were related to overall body weight. The data emerging from this study were evaluated using the Student t-test. Conclusions: one-month exposure led to a decrease in hypothalamic NA and an increase in rat spleen weight; increase in CA concentration in the adrenals was initially insignificant, by the end of a 2-month exposure it reached the level of statistical significance; serum concentrations of B, T3 and T4 remained unaffected and so was the weight of the body, liver, lungs, suprarenals and the hypothalamus of exposed rats; at the concentrations used, NO2 and CO acted as synergists producing a mild stressogenic reaction affecting the activity of the sympathico-adrenomedullary system of exposed rats.     

Transient depletion of lung glutathione by diethylmaleate enhances oxygen toxicity

Diethylmaleate (DEM) decreases glutathione (GSH) levels in various organs by enzymatic conjugation with reduced GSH catalyzed by GSH transferase. We have examined levels of GSH, glutathione reductase (GR), and glucose-6-phosphate dehydrogenase (G6PD) in lungs of 200-250-g rats after intraperitoneal injection of 0.5 or 1 g DEM/kg body wt. The GSH levels are severely depressed at 2 and 4 h but have essentially recovered by 12 and 24 h after either dose of DEM. The GR and G6PD activities in the 1 g/kg group are depressed at 4 h to a lesser extent than the GSH levels and also return to normal by 12 and 24 h. These enzymes are not affected in the 0.5 g/kg group. To determine whether these transient decreases in GSH and related enzymes affected O2 tolerance, we exposed rats injected with DEM to greater than 98% O2 and found that halftime (t1/2) for survival was decreased in rats receiving both 0.5 and 1 g DEM/kg body wt when compared with untreated or saline-injected controls (t1/2 control, 74 h; 0.5 g DEM, 59 h; 1 g DEM, 53 h). No deaths occurred in air controls at 1 mg/kg DEM for up to 5 days. DEM, in itself, caused no morphological alteration of the lung. Thus a decrease in lung GSH and related enzymes, occurring by 4 h and reversed by 12 h, has a significant effect on the subsequent progression of lung pathology and indicates that early biochemical events occurring in lungs exposed to hyperoxia may be very important in determining the degree of longer-term damage to rat lungs.     

Levels of DNA damage in blood leukocyte samples from non-diabetic and diabetic female rats and their fetuses exposed to air or cigarette smoke

The objective of the present study was to evaluate DNA damage level in blood leukocytes from diabetic and non-diabetic female Wistar rats exposed to air or to cigarette smoke, and to correlate the findings with levels of DNA damage detected in blood leukocyte samples from their fetuses. A total of 20 rats were distributed into four experimental groups: non-diabetic (control; G1) and diabetic exposed to filtered air (G2); non-diabetic (G3) and diabetic (G4) exposed to cigarette smoke. Rats placed into whole-body exposure chambers were exposed for 30min to filtered air (control) or to tobacco smoke generated from 10 cigarettes, twice a day, for 2 months. Diabetes was induced by a pancreatic beta-cytotoxic agent, streptozotocin (40mg/kgb.w.). At day 21 of pregnancy, each rat was anesthetized and humanely killed to obtain maternal and fetal blood samples for genotoxicity analysis using the alkaline comet assay. G2, G3 and G4 dams presented higher DNA damage values in tail moment and tail length as compared to G1 group. There was a significant positive correlation between DNA damage levels in blood leukocyte samples from G2 and G3 groups (tail moment); G3 and G4 groups (tail length) and G3 group (tail intensity) and their fetuses. Thus, this study showed the association of severe diabetes and tobacco cigarette smoke exposure did not exacerbate levels of maternal and fetal DNA damages related with only diabetes or cigarette smoke exposure. Based on the results obtained and taking into account other published data, maternal diabetes requires rigid clinical control and public health and education campaigns should be increased to encourage individuals, especially pregnant women, to stop smoking.     

Effect of nitrous oxide on nickel deprivation in rats

Because nickel may have a biological function in a pathway in which vitamin B₁₂ is important, an experiment was performed to determine the effects of nitrous oxide exposure in rats deprived of nickel. Exposure to nitrous oxide (N₂O) causes inactivation of cobalamin and a subsequent decrease in the vitamin B₁₂-dependent enzymes methionine synthase and methylmalonyl CoA mutase. Rats were assigned to dietary groups of 12 in a factorially arranged experiment with dietary variables of nickel (0 or 1 μg/g) and vitamin B₁₂ (0 or 50 ng/g). After 6 wk, one-half of the rats from each dietary group were exposed to 50% N₂O/50% O₂ for 90 min/d for the last 28 d of the experiment. Vitamin B₁₂, N₂O, or their interaction had numerous effects; classical findings included N₂O-induced reduction in plasma vitamin B₁₂ and decreases in the vitamin B₁₂-dependent enzymes. Inactivation of vitamin B₁₂ by N₂O, however, did not exacerbate signs of nickel deprivation, possibly because the rats were able to metabolically compensate to N₂O exposure. Mention of a trademark or proprietary product in this article does not constitute a guarantee or warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.     

Milk transfer of inorganic mercury to suckling rats

The transport of mercury into rat milk, and uptake in the suckling offspring was studied after peroral administration of inorganic mercury to lactating control rats, and to rats fed selenite in the diet. On day 8, 9, 10, or 11 of lactation, dams were administered a single oral dose of 0.1, 0.4, 0.7, 1.3, or 5.8 mg Hg/kg bw labeled with 203mercuric acetate. There was a linear relationship between mercury concentrations in dam's plasma and milk. The level of mercury in milk was approximately 25% of the level in plasma. After 3 d, milk levels were reduced to half the levels at 24 h. In the suckling offspring, exposed to mercury via milk during 3 d, the mercury level in blood was approximately 1% of the level in maternal blood. Mercury concentration in milk was linearly correlated to the levels in kidney, liver, and brain in the suckling offspring after 3 d exposure to mercury via milk. Selenite treatment of rats, 1.3 micrograms Se/g diet for 5 mo, resulted in increased transport of mercury to milk, probably because of increased plasma levels of mercury. However, selenite treatment of the dams did not cause any increased tissue levels of mercury in the suckling offspring.     

Biomonitoring of environmental pollution hazards from a nickel smelter waste dump

Longterm field exposure study was carried out on 10 rabbits placed for 6 months in a bioindication station located about 3 km downwind of a disposal site of nickel smelter waste dump. As revealed by the method of atomic absorption spectrophotometry, all of these animals showed elevated nickel and chromium levels in their body organs and hair. These findings were paralleled by histologic abnormalities in the lungs and liver tissues. Average dustfall values at the site of exposure did not exceed 5.5 g X m-2 X 30 d-1 during the period of observation. Dustfall deposits in this location contained nickel and chromium in amounts that were higher than in control locality. Analogous experiments on Wistar rats were carried out in a laboratory exposure chamber (exposure 4 h/day, 5 days/week, for a period of 6 months). After exposures to 50 mg X m-3 of metallic dust, lung parenchyma of rats was characterized by the presence of dust particles in various phases of phagocytosis as well as the presence of badly damaged or disintegrated alveolar macrophage cells, which pointed to metallic aerosol toxicity for biomembranes. The technique of air pollution biomonitoring on animals, correlated with the data on ambient air concentrations of the suspended particulate matter and its content of trace metals, appears to be a well suitable tool in establishing the potential air pollution hazards to the exposed populations living in the area of concern.     

Influence of vitamin E on polyamine metabolism in ozone-exposed rat lungs

The influence of vitamin E (E) on lung polyamine metabolism of rats exposed to ozone (O3) was examined. Rats fed diets wither E-deficient or supplemented with 1000 IU E/kg were exposed to 0.5 +/- 0.05 ppm O3 or filtered room air continuously for 5 days. They were then sacrificed and their lungs were analyzed for biochemical changes. Lung E content was strongly associated with the dietary level, and increased (36%, P less than 0.05) after O3 exposure only in E-supplemented rats. Lung polyamine metabolism was not affected in the air-control rats by E level, but increased after O3 exposure in both dietary groups. The activities of ornithine decarboxylase and S-adenosylmethionine decarboxylase were elevated above air controls. However, the increases were significant only for E-deficient rats when compared to E-supplemented rats. After O3 exposure, putrescine increased significantly in both dietary groups; spermidine increased but was significantly higher only in the E-deficient group; and spermine remained unchanged in both dietary groups. Elevated E content of supplemented rat lungs after O3 exposure may represent its mobilization under oxidant stress. Increased polyamine metabolism of E-deficient rats suggests either a greater sensitivity to injury by O3 or a possible antioxidant function for polyamines compensating for E deficiency.     

Lactate dehydrogenase isoenzyme pattern and total LDH activity in the lung and liver of rats chronically exposed to low and high oxygen concentrations.

Young adult rats were continuously exposed for 44 and 84 days to environments containing 9–11%, 20%, and 80% oxygen. Low and high oxygen atmospheres were achieved by using boxes laminated with silicone rubber membranes which have a differing permeability for oxygen on one side and for carbon dioxide and nitrogen on the other. Animals exposed to both extreme concentrations significantly slowed body growth, and the weight of the lungs was proportionally less. The pattern of LDH isoenzymes in the lung showed the presence of all five characteristically changing isoenzymes in relation to oxygen concentration. A marked increase of M subunits in the LDH in lungs of rats exposed to low oxygen indicated a higher tissue concentration of lactate. Thus, the percentage of M subunits was significantly higher in low oxygen and significantly lower in lungs of rats exposed to high oxygen as compared to controls. Under the same experimental conditions there were no changes in the liver LDH isoenzyme pattern. Total LDH activity in the lungs of rats exposed to either extreme oxygen atmosphere was significantly elevated as compared to controls kept at an ambient atmosphere. It is concluded that chronic exposure of rats to low as well as to high oxygen was injurious to the lung tissue, as evidenced by total LDH activity. Thus, LDH isoenzyme pattern in the lung reflected the actual gas exposure (pO₂), rather than local tissue metabolism.     

Quantitating the frequency of initiation and cH-ras mutation in in situ N-methyl-N-nitrosourea-exposed rat mammary gland

Mammary carcinogenesis is a multistep process consisting minimally of initiation and promotion/progression stages. The rate-limiting stage in the carcinogenesis process is undetermined but can in part be addressed by estimating the frequency of initiation, a heritable early event. Here, we use an in vivo limiting dilution transplantation assay to estimate initiation frequency in a rat mammary epithelial stem-like cell population that was exposed in situ to 50 mg/kg N-methyl-N-nitrosourea (NMU) administered i.v. We estimate that this dose resulted in the killing of 65% of exposed mammary cells. Known numbers of cells surviving NMU exposure were grafted into fat-pads of recipient rats in which the cells grew and differentiated into structurally and functionally normal mammary glands. Recipient rats were hormonally manipulated to provide maximal promotion of initiated cells. Mammary carcinomas developing at graft sites were quantitated over a 2-year period. Based on these results, we estimate that at least 1 surviving NMU-exposed mammary cell in 7,200 was initiated. Seventeen % of these graft site carcinomas had an activated H-ras oncogene with a G to A mutation in codon 12. This suggests that at least 1 mammary cell in 43,000 was mutated in this fashion by in situ exposure to NMU. These data suggest that cH-ras represents approximately 1 of 5 of the initiation events produced by NMU exposure of rat mammary glands.