Absorption of inhaled NO(2).

Nitrogen dioxide (NO(2)), a sparingly water-soluble pi-radical gas, is a criteria air pollutant that induces adverse health effects. How is inhaled NO(2)(g) incorporated into the fluid microfilms lining respiratory airways remains an open issue because its exceedingly small uptake coefficient (gamma approximately 10(-7)-10(-8)) limits physical dissolution on neat water. Here, we investigate whether the biological antioxidants present in these fluids enhance NO(2)(g) dissolution by monitoring the surface of aqueous ascorbate, urate, and glutathione microdroplets exposed to NO(2)(g) for approximately 1 ms via online thermospray ionization mass spectrometry. We found that antioxidants catalyze the hydrolytic disproportionation of NO(2)(g), 2NO(2)(g) + H(2)O(l) = NO(3)(-)(aq) + H(+)(aq) + HONO, but are not consumed in the process. Because this function will be largely performed by chloride, the major anion in airway lining fluids, we infer that inhaled NO(2)(g) delivers H(+), HONO, and NO(3)(-) as primary transducers of toxic action without antioxidant participation.

Inhibition of vertebral endplate perfusion results in decreased intervertebral disc intranuclear diffusive transport.

Impaired nutrition of the intervertebral disc has been hypothesized to be one of the causes of disc degeneration. However, no causal relationship between decreased endplate perfusion and limited nutrient transport has been demonstrated to support this pathogenic mechanism. To determine the importance of endplate perfusion on solute diffusion into the nucleus pulposus and to show causality of endplate perfusion on intranuclear diffusion in large animal lumbar intervertebral discs, diffusive transport into ovine lumbar intervertebral discs was evaluated after inhibiting adjacent vertebral endplate perfusion. Partial perfusion blocks were created in vertebrae close and parallel to both endplates of lumbar discs of anaesthetized sheep. To assess diffusivity of small molecules through the endplate, N2O was introduced into the inhalation gas mixture and concentrations of intranuclear N2O were measured for 35 min thereafter. Post mortem, procion red was infused through the spinal vasculature and perfusion through the endplate was assessed by quantifying the density of dye-perfused endplate vascular buds in histology sections. Perfusion of the endplates overlying the nucleus pulposus was inhibited by almost 50% in the partially blocked discs relative to the control discs. There was also a nine-fold decreased transport rate of intranuclear N2O in partially blocked discs compared with control discs. The density of perfused endplate vascular buds correlated significantly to the amount of transported intranuclear N2O (r2 = 0.52, P = 0.008). The vertebral endplate was demonstrated to be the main route of intravascular solute transport into the nucleus pulposus of intervertebral discs, and inhibition of endplate perfusion can cause inhibited solute transport into the disc intranuclear tissue.

Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants.

In order to investigate nocturnal uptake and assimilation of NO2 by C3 and crassulacean acid metabolism (CAM) plants, they were fumigated with 4 microl l(-1) 15N-labeled nitrogen dioxide (NO2) for 8 h. The amount of NO2 and assimilation of NO2 by plants were determined by mass spectrometry and Kjeldahl-nitrogen based mass spectrometry, respectively. C3 plants such as kenaf (Hibiscus cannabinus), tobacco (Nicotiana tabacum) and ground cherry (Physalis alkekengi) showed a high uptake and assimilation during daytime as high as 1100 to 2700 ng N mg(-1) dry weight. While tobacco and ground cherry strongly reduced uptake and assimilation of NO2 during nighttime, kenaf kept high nocturnal uptake and assimilation of NO2 as high as about 1500 ng N mg(-1) dry weight. Stomatal conductance measurements indicated that there were no significant differences to account for the differences in the uptake of NO2 by tobacco and kenaf during nighttime. CAM plants such as Sedum sp., Kalanchoe blossfeldiana (kalanchoe) and Aloe arborescens exhibited nocturnal uptake and assimilation of NO2. However, the values of uptake and assimilation of NO2 both during daytime and nighttime was very low (at most about 500 ng N mg(-1) dry weight) as compared with those of above mentioned C3 plants. The present findings indicate that kenaf is an efficient phytoremediator of NO2 both during daytime and nighttime.

Nitric oxide adsorbed on zeolites: EPR studies.

CW-EPR studies of NO adsorbed on sodium ion-exchanged zeolites were focused on the geometrical structure of NO monoradical and (NO)2 biradical formed on zeolites. The EPR spectrum of NO monoradical adsorbed on zeolite can be characterized by the three different g-tensor components and the resolved y-component hyperfine coupling with the 14N nucleus. Among the g-tensor components, the value of g(zz) is very sensitive to the local environment of zeolite and becomes a measure of the electrostatic field in zeolite. The temperature dependence of the g-tensor demonstrated the presence of two states of the Na-NO adduct, in rigid and rotational states. The EPR spectra of NO adsorbed on alkaline metal ion-exchanged zeolite and their temperature dependency are essentially the same as that on sodium ion-exchanged zeolite. On the other hand, for NO adsorbed on copper ion-exchanged zeolite it is known that the magnetic interaction between NO molecule and paramagnetic copper ion are observable in the spectra recorded at low temperature. The signals assigned to (NO)2 biradical were detected for EPR spectrum of NO adsorbed on Na-LTA. CW-EPR spectra as well as their theoretical calculation suggested that the two NO molecules are aligned along their N-O bond axes. A new procedure for automatical EPR simulation is described which makes it possible to analyze EPR spectrum easily. In the last part of this paper, some instances when other nitrogen oxides were used as a probe molecule to characterize the zeolite structure, chemical properties of zeolites, and dynamics of small molecules were described on the basis of selected literature data reported recently.

Effect of ozone and nitrogen dioxide on the permeability of bronchial epithelial cell cultures of non-asthmatic and asthmatic subjects.

BACKGROUND: Although epidemiological as well as in vivo exposure studies suggest that ozone (O3) and nitrogen dioxide (NO2) may play a role in airway diseases such as asthma, the underlying mechanisms are not clear. OBJECTIVE: Our aim was to investigate the effect of O3 and NO2 on the permeability of human bronchial epithelial cell (HBEC) cultures obtained from non-atopic non-asthmatic (non-asthmatics) and atopic mild asthmatic (asthmatics) individuals. METHODS: We cultured HBECs from bronchial biopsies of non-asthmatics and asthmatics, and exposed these for 6 h to air, 10 to 100 parts per billion (p.p.b.) O3, or to 100 to 400 p.p.b. NO2, and assessed changes in electrical resistance (ER) and movement of 14C-BSA across the cell cultures. RESULTS: Although exposure to either O3 or NO2 did not alter the permeability of HBEC cultures of non-asthmatics, 10 to 100 p.p.b. O3 and 400 p.p.b. NO2 significantly decreased the ER of HBEC cultures of asthmatics, when compared with exposure to air. Additionally, 10, 50 and 100 p.p.b. O3 led to a significant increase in the movement of 14C-BSA across asthmatic HBEC cultures, after 6 h of exposure (medians = 1.73%; P < 0.01, 1.50%; P < 0.05 and 1.53%, P < 0.05, respectively), compared with air exposed cultures (median = 0.89%). Similarly, exposure for 6 h to both 200 and 400 p.p.b. NO2 significantly increased the movement of 14C-BSA across asthmatic HBEC cultures, when compared with air exposure. A comparison of data obtained from the two study groups demonstrated that 10 to 100 p.p.b. O3- and 200 to 400 p.p.b. NO2-induced epithelial permeability was greater in cultures of asthmatics compared with non-asthmatics. CONCLUSION: These results suggest that HBECs of asthmatics may be more susceptible to the deleterious effects of these pollutants. Whether in patients with asthma the greater susceptibility of bronchial epithelial cells to O3 and NO2 contributes to the development of the disease, or is a secondary characteristic of this condition, remains to be determined.

Urinary hydroxyproline as a biomarker of effect after exposure to nitrogen dioxide.

A cross-sectional study was carried out on two groups of subjects differently exposed to nitrogen dioxide in order to test the urinary hydroxyproline ratio (UHP/mg/24 h/m(2)) as a biomarker of effect after exposure to this pollutant. UHP was determined in samples of 58 subjects divided into two groups comparable to as lifestyle and training. The first group was composed of 29 subjects who used to do jogging in urban areas polluted by nitrogen dioxide. The second group was made up of 29 subjects who used to do jogging in non-polluted countryside areas. The mean concentration of UHP of urban joggers was 25.02+/-9.21 mg/24 h/m(2), whereas in those training in the countryside it was 13.78+/-6.68 mg/24 h/m(2). Thus, UHP was higher in subjects training in areas polluted by nitrogen dioxide than in the subjects training in non-polluted areas.

An air pollution model for use in epidemiological studies: evaluation with measured levels of nitrogen dioxide and benzene.

The aim of the study was to evaluate the predictions derived from the Danish Operational Street Pollution Model (OSPM) when the input data are obtained by simple methods that could be used in large-scale epidemiological studies. The model calculations were thus compared with passive sampler measurements of nitrogen dioxide and benzene at 103 street locations in Copenhagen, Denmark, and at 101 locations in rural areas. Data on traffic and street configuration were collected by means of a simple registration scheme in which forms were filled out by local municipal authorities. Meteorological data were derived from routine measurements at Copenhagen airport, and data on background air pollution were based on a simple empirical model. Differences in air pollution levels between rural areas and Copenhagen and differences in nitrogen dioxide concentrations at various locations in Copenhagen were well reproduced by the OSPM. The correlation coefficients (r) between the measured and the predicted half-year average concentrations of nitrogen dioxide in Copenhagen were between 0.75 and 0.80 for various degrees of precision of the input data for the model. The results indicate that the OSPM used with the presented methods for generation of input data might be useful in assessing long-term exposure to air pollutants in epidemiological studies.

NO2-induced generation of extracellular reactive oxygen is mediated by epithelial lining layer antioxidants.

Nitrogen dioxide (NO2) is an environmental oxidant that causes acute lung injury. Absorption of this aqueous insoluble gas into the epithelial lining fluid (ELF) that covers air space surfaces is, in part, governed by reactions with ELF constituents. Consequently, NO2 absorption is coupled to its chemical elimination and the formation of ELF-derived products. To investigate mechanisms of acute epithelial injury, we developed a model encompassing the spatial arrangements of the lung surface wherein oxidation of cell membranes immobilized below a chemically defined aqueous compartment was assessed after NO2 exposures. Because aqueous-phase unsaturated fatty acids displayed minimal NO2 absorptive activity, these studies focused on glutathione (GSH) and ascorbic acid (AH2) as the primary NO2 absorption substrates. Results demonstrated that membrane oxidation required both gasphase NO2 and aqueous-phase GSH and/or AH2. Membrane oxidation was antioxidant concentration and exposure duration dependent. Furthermore, studies indicated that GSH- and AH2-mediated NO2 absorption lead to the production of the reactive oxygen species (ROS) O-2. and H2O2 but not to .OH and that Fe-O2 complexes likely served as the initiating oxidant. Similar results were also observed in combined systems (GSH + AH2) and in isolated rat ELF. These results suggest that the exposure-induced prooxidant activities of ELF antioxidants generate extracellular ROS that likely contribute to NO2-induced cellular injury.

NO2 reactive absorption substrates in rat pulmonary surface lining fluids.

Inhaled 'NO2 is absorbed by a free radical-dependent reaction mechanism that localizes the initial oxidative events to the extracellular space of the pulmonary surface lining layer (SLL). Because 'NO2 per se is eliminated upon absorption, most likely the SLL-derived reaction products are critical to the genesis of 'NO2-induced lung injury. We utilized analysis of the rate of 'NO2 disappearance from the gas phase to determine the preferential absorption substrates within rat SLL. SLL was obtained via bronchoalveolar lavage and was used either as the cell-free composite or after constituent manipulation [(i) dialysis, treatment with (ii) N-ethylmaleimide, (iii) ascorbate oxidase, (iv) uricase, or (v) combined ii + iii]. Specific SLL constituents were studied in pure chemical systems. Exposures were conducted under conditions where 'NO2 is the limiting reagent and disappears with first-order kinetics ([NO2]0 < or = 10 ppm). Reduced glutathione and ascorbate were the principle rat SLL absorption substrates. Nonsulfhydryl amino acids and dipalmitoyl phosphatidylcholine exhibited negligible absorption activity. Whereas uric acid and vitamins A and E displayed rapid absorption kinetics, their low SLL concentrations preclude appreciable direct interaction. Unsaturated fatty acids may account for < or = 20% of absorption. The results suggest that water soluble, low molecular weight antioxidants are the preferential substrates driving 'NO2 absorption. Consequently, their free radicals, produced as a consequence of 'NO2 exposure, may participate in initiating the 'NO2-induced cascade, which results in epithelial injury.

Simulation of the uptake of a reactive gas in a rat respiratory tract model with an asymmetric tracheobronchial region patterned on complete conducting airway cast data.

Generally, the uptake of reactive gases by the respiratory tract is simulated assuming that all paths from the trachea to the most distal airspaces are equivalent. As this is not the case, especially for nonhumans, the adequacy of this approach to predict doses that can be useful in the fields of toxicology and risk assessment is subject to question. To explore this issue, a dosimetry model is developed which combines the use of one-dimensional convection-dispersion equations in conjunction with multiple path anatomic models so that the dosimetry model simultaneously simulates transport and uptake in all the airways and airspaces of the anatomic model. For this work, the anatomic model of the tracheobronchial (TB) region is patterned on cast data which describe the dimensions and branching network of the 4807 airways of the TB region of a rat. Distal to each of the 2404 terminal bronchioles of the anatomical model, the air space is modeled as a single path. The results presented are preliminary; they focus on the predictions themselves to obtain an understanding of what the model has to say about uptake in a complex set of branching airways. Results include the following predictions: (1) Regardless of path there is a similarity along different paths in the shape of concentration profiles as well as a similarity in the shape of dose profiles. (2) Along a path in the TB or pulmonary region, dose decreases distally. (3) Generally, proximal alveolar region (PAR, a region of major morphological damage due to O3 and NO2) dose decreases the more distal the PAR. (4) There is considerable variation in the doses of the different airways or alveolar surfaces in the same generation. (5) The maximum and minimum PAR doses do not correspond to paths with, respectively, the smallest and largest number of generations from the trachea to the PAR. (6) The ratio of the maximum to minimum PAR dose is very sensitive to tidal volume. These results give a more realistic understanding of respiratory tract gas transport and uptake. The model also predicts aspects that equivalent path models cannot, such as the dose distribution of different but morphologically equivalent sites.

Lung injury following exposure of rats to relatively high mass concentrations of nitrogen dioxide.

Human inhalation exposures to relatively high mass concentrations of the oxidant gas nitrogen dioxide (NO2) can result in a variety of pulmonary disorders, including life-threatening pulmonary edema, pneumonia, and bronchiolitis obliterans. Inasmuch as most experimental studies to date have examined NO2-induced lung injury following exposures to near ambient or supra-ambient concentrations of NO2, e.g., < or = 50 ppm, little detailed information about the pulmonary injurious responses following the acute inhalation of higher NO2 concentrations that are more commensurate with some actual human exposure conditions is currently available. Described in this report are the results from a series of investigations in which various aspects of the inhalation toxicity of high concentrations of NO2 have been examined in laboratory rats. In the first component of our study, we characterized the kinetic course of development of lung injury following acute exposures to high concentrations of NO2 delivered over varying durations, and we assessed the relative importance of NO2 exposure concentration versus exposure time in producing lung injury. For a given exposure duration, the resulting severity of lung injury was found to generally scale proportionately with inhaled mass concentration, whereas for a given concentration of inhaled NO2, the magnitude of resulting injury was not directly proportional to exposure duration. Moreover, evidence was obtained that indicated exposure concentration is more important than exposure time when high concentrations of NO2 are inhaled. In a second component of our investigation, we assessed the pulmonary injurious response that occurs when NO2 is inhaled during very brief, 'high burst' exposures to very high concentrations of NO2. Such exposures resulted in significant lung injury, with the magnitude of such injury being directly proportional to exposure concentration. Comparisons of results obtained from this and the first component studies additionally revealed that brief exposures to the very high concentrations of NO2 are more hazardous than longer duration exposures to lower concentrations. In a third study series, we examined pre-exposure, exposure, and post-exposure modifiers of NO2-induced lung injury, including dietary taurine, minute ventilation, and post-exposure exercise. Results from these studies indicated: (i) dietary taurine does not protect the rat lung against high concentration NO2 exposure, (ii) the severity of acute lung injury in response to NO2 inhalation is increased by an increase in minute ventilation during exposure, and (iii) the performance of exercise after NO2 exposure can significantly enhance the injurious response to NO2.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanisms of pulmonary NO2 absorption.

Although NO2-induced cytotoxic responses have been well characterized, the specific mechanisms responsible for initiating toxicity remain equivocal. The inhomogeneous distribution of epithelial injury suggests that differential interactions between NO2 and the lung surfaces may contribute to the extent of regional responses. Consequently, we have initiated studies to characterize the mechanisms which govern NO2 absorption and the initiation of the toxic cascade. Due to limitations in whole animal models, we have utilized numerous in vitro exposure models. Herein we examine our recent investigations. In brief synopsis: NO2 uptake is governed by reaction between inhaled NO2 and constituents of the pulmonary surface lining layer (SLL). The predominant reaction pathway involves hydrogen abstraction producing HNO2 and an organic radical. NO2 uptake is first-order with respect to NO2 ([NO2] < 10 ppm), is aqueous substrate-dependent, and is saturable. Conditions at the gas/liquid interface proper modulate the rate of transfer into the aqueous phase. Most likely, NO2 does not diffuse unreacted through the SLL. Absorption is proportional to inspired dose. The clearance efficiency may be modulated by ventilation frequency and the effective surface area of the exposed air space surfaces. We propose that the profile and concentration of SLL constituents mediate both the dosimetry and the extent of epithelial responses. Due to differential lining layer conditions, the relationship between absorbed dose and response may be complex and may exhibit anatomic and host variability.

[Effects of low concentrations of NO2 on alveolar permeability and glutathione peroxidase in healthy subjects]. / Virkninger af mindre NO2-koncentrationer på alveolaer permeabilitet og glutationperoxidase blandt raske mennesker.

Potential toxic effects of prolonged NO2 exposure below the current threshold limit value (TLV) were examined in 14 healthy, non-smoking adults. The subjects were exposed to 2,3 ppm NO2 and to clean air for five hours with a one week interval between exposures. Physiological and biochemical measurements were obtained during exposure and the following 24 hours after. A 14% decrease in serum glutathione peroxidase activity (GSH-Px) was observed 24 hours after the start of the NO2 exposure while indications of a 22% decrease in alveolar permeability were found 11 hours after the start. There were no indications of mucous membrane irritation or of decreased lung function during or after NO2 exposures. The results support the assumption that a delayed response is a feature of the human reaction to NO2 even below the current TLV of three ppm, and they stress the importance of an extended period of observation in future NO2 exposure studies.

Kinetics of NO2 air space absorption in isolated rat lungs.

We previously showed, during quasi-steady-state exposures, that the rate of inhaled NO2 uptake displays reaction-mediated characteristics (J. Appl. Physiol. 68: 594-603, 1990). In vitro kinetic studies of pulmonary epithelial lining fluid (ELF) demonstrated that NO2 interfacial transfer into ELF exhibits first-order kinetics with respect to NO2, attains [NO2]-dependent rate saturation, and is aqueous substrate dependent (J. Appl. Physiol. 71: 1502-1510, 1991). We have extended these observations by evaluating the kinetics of NO2 gas phase disappearance in isolated ventilating rat lungs. Transient exposures (2-3/lung at 25 degrees C) employed rebreathing (NO2-air) from a non-compliant continuously stirred closed chamber. We observed that 1) NO2 uptake rate is independent of exposure period, 2) NO2 gas phase disappearance exhibited first-order kinetics [initial rate (r*) saturation occurred when [NO2] > 11 ppm], 3) the mean effective rate constant (k*) for NO2 gas phase disappearance ([NO2] < or = 11 ppm, tidal volume = 2.3 ml, functional residual capacity = 4 ml, ventilation frequency = 50/min) was 83 +/- 5 ml/min, 4) with [NO2] < or = 11 ppm, k* and r* were proportional to tidal volume, and 5) NO2 fractional uptakes were constant across [NO2] (< or = 11 ppm) and tidal volumes but exceeded quasi-steady-state observations. Preliminary data indicate that this divergence may be related to the inspired PCO2. These results suggest that NO2 reactive uptake within rebreathing isolated lungs follows first-order kinetics and displays initial rate saturation, similar to isolated ELF.(ABSTRACT TRUNCATED AT 250 WORDS)

Rat model to investigate the treatment of acute nitrogen dioxide intoxication.

1. The pulmonary toxic events induced by acute nitrogen dioxide (NO)2 exposure were studied in the rat to develop an inhalation model to investigate therapeutic measures. 2. A good correlation was observed between the lung weights and severity of the atypical pneumonitis. The pulmonary effects observed, became more pronounced with increasing NO2 concentrations (0, 25, 75, 125, 175 or 200 ppm, 1 ppm NO2 = 1.88 mg m-3 NO2) and exposure times (5, 10, 20 or 30 min). 3. An adequate NO2 concentration is 175 ppm, because it can induce a severe lung injury without mortality. This makes it possible to investigate suitable therapeutic interventions for several days. 4. Following acute inhalatory NO2 intoxication, transformation of NO2 to nitrate is presumably more notable than transformation to nitrite. 5. The transformation of NO2 to nitrate in lung tissue causes a slight increase in the serum nitrite concentration, which does not induce measurable formation of methaemoglobin. 6. Presumably, methaemoglobin does not contribute to the toxicity of NO2 intoxication.

Concentration-response relationships of rat lungs to exposure to oxidant air pollutants: a critical test of Haber's Law for ozone and nitrogen dioxide.

Exposure protocols were designed to ask whether lung damage in rats exposed to either ozone or nitrogen dioxide is proportional to dose rate or to cumulative dose. Thus, the response of rats to a constant product of concentration of oxidant air pollutant and time of exposure (C x T) was evaluated for 3-day exposures over a fourfold range of concentrations of ozone (0.2-0.8 ppm) or of nitrogen dioxide (3.6-14.4 ppm) for exposure durations of 6-24 hr per day. The response of rat lungs was quantified by changes in total protein content of lung lavage supernatants or by changes in content of specific cell types in lung lavage pellets. The results of these experiments clearly demonstrate that acute lung damage is a function of cumulative dose (that is, C x T product) for the three highest dose rates tested. However, when exposure duration is extended to include the entire 24-hr period (the lowest dose rate tested), there is a marked attenuation of pulmonary response. Rats were also exposed to mixtures of ozone and nitrogen dioxide with the C x T product held constant. Our results clearly demonstrate that when rats are exposed to combinations of ozone and nitrogen dioxide, lung damage is a function of peak concentration rather than a function of cumulative dose. This deviation from Haber's Law is attributed to a concentration-dependent, synergistic (greater than additive) response to this specific mixture of oxidant air pollutants.

Transfer of NO2 through pulmonary epithelial lining fluid.

Absorption of inhaled NO2 across the pulmonary gas/tissue interface is principally governed by chemical reaction(s) rather than by physical solubility. While the kinetics of NO2 transfer into reactant-containing aqueous solutions appear to be bulk phase independent, it is unclear whether unreacted NO2 diffuses appreciably through the epithelial lining fluid (ELF) to cellular compartments. We avoided the difficulties associated with directly quantifying NO2 dissolved in biological fluids by indirectly determining the potential for NO2 penetration to underlying tissues. An in vitro system was developed which horizontally suspended a wettable, gas permeable, fibrous material between two gas chambers. Aqueous substrates were applied to the sieve material and NO2 (10.9 ppm) was introduced into one chamber and sampled for in the other. O2 served as a tracer gas. We determined the influence of ELF, a model biochemical (reduced glutathione; GSH), and PO4 buffer (control) on NO2 transfer as evaluated by "breakthrough time." (A) Both O2 and NO2 rapidly diffused through the sieve material when dry. Under PO4 wetted conditions, O2 continued to penetrate rapidly but NO2 transfer was slightly inhibited relative to O2. (B) Addition of GSH (1 mM) significantly prolonged NO2 breakthrough time. Increasing initial [GSH] resulted in concomitant prolongation of NO2 breakthrough time. (C) We observed a direct correlation between oxidation of sieve GSH and NO2 breakthrough. (D) Freshly harvested rat ELF inhibited NO2 transfer in a concentration-dependent manner similar to GSH. These data suggest that in the presence of reactant solutes, unreacted NO2 does not penetrate through the ELF layer. Reactive absorption must, therefore, occur primarily within the ELF compartment so that reaction products which induce subsequent toxicity are generated as a result of the initial uptake interactions.

Reactive absorption of nitrogen dioxide by pulmonary epithelial lining fluid.

In a previous study (J. Appl. Physiol. 68: 594-603, 1990) in isolated rat lungs, we suggested that the rate of pulmonary air space absorption of inhaled NO2 is limited, in part, by chemical reaction(s) rather than by physical solubility. Because the initial site of primary absorption interactions involves the epithelial lining fluid (ELF), we investigated whether ELF-NO2 interactions could account for pulmonary NO2 reactive absorption. Rat ELF, obtained by bronchoalveolar lavage (BAL), was compared with a model chemical system (reduced glutathione, GSH). In vitro exposures (NO2-air) used constant gas flow and planar gas-liquid interfaces. 1) Solvent pH notably altered NO2 uptake by GSH but to a lesser extent by BAL. 2) Uptake displayed [GSH]-dependent saturation. [ELF] in BAL was augmented by sequential lavage (lavagate reuse) of multiple lungs. Uptake was proportional to [ELF] but did not saturate under these exposure conditions. 3) The uptake rate exhibited [NO2] dependence. However, relative to increasing [NO2], fractional uptakes decreased for BAL and 1 mM GSH but not for 10 mM GSH. 4) Altered convective gas flow produced nonlinear increments in uptake (10 mM GSH) and substantial decrements in fractional uptake. 5) Arrhenius plots [ln(r) vs. 1/T, where r is reaction rate and T is absolute temperature (degree K)] for BAL and 1 mM GSH yielded respective activation energies of 4,952 and 4,149 kcal.g-1.mol-1 and degree of change in the rate of NO2 uptake per 10 degrees C (Q10) of 1.32 and 1.25. These results imply that the rate of NO2 uptake into rat ELF, like intact lung, is limited, in part, by chemical reaction(s).(ABSTRACT TRUNCATED AT 250 WORDS)

Reactive uptake governs the pulmonary air space removal of inhaled nitrogen dioxide.

With the use of an isolated rat lung model, we investigated pulmonary air space absorption kinetics of the reactive gas NO2 in an effort to determine the contributory role of chemical reaction(s) vs. physical solubility. Unperfused lungs were employed, because vascular perfusion had no effect on acute (0- to 60-min) NO2 absorption rates. We additionally found the following: 1) Uptake was proportional to exposure rates (2-14 micrograms NO2/min; 10-63 ppm; 37 degrees C) but saturated with exposures greater than or equal to 14 micrograms NO2/min. 2) Uptake was temperature (22-48 degrees C) dependent but, regardless of temperature, attained apparent saturation at 10.6 micrograms NO2/min. 3) Lung surface area (SA) was altered by increasing functional residual capacity (FRC). Expanded SA (8 ml FRC) and temperature (48 degrees C) both raised fractional uptakes (greater than or equal to 0.81) relative to 4 ml FRC, 37 degrees C (0.67). Uptake rates normalized per unit estimated SA revealed no independent effect of FRC on fractional uptake. However, temperature produced a profound effect (48 degrees C = 0.93; 4 and 8 ml FRC = 0.54). 4) Arrhenius plots (ln k' vs. 1/T), which utilized derived reactive uptake coefficients (k'), showed linearity (r2 = 0.94) and yielded an activation energy of 7,536 kcal.g-1.mol-1 and Q10 of 1.43, all consistent with a reaction-mediated process. These findings, particularly the effects of temperature, suggest that acute NO2 uptake in pulmonary air spaces is, in part, rate limited by chemical reaction of NO2 with epithelial surface constituents rather than by direct physical solubility.