Neuronal modulation of lung injury induced by polymeric hexamethylene diisocyanate in mice.

1,6-Hexamethylene diisocyanate biuret trimer (HDI-BT) is a nonvolatile isocyanate that is a component of polyurethane spray paints. HDI-BT is a potent irritant that when inhaled stimulates sensory nerves of the respiratory tract. The role of sensory nerves in modulating lung injury following inhalation of HDI-BT was assessed in genetically manipulated mice with altered innervation of the lung. Knockout mice with a mutation in the low-affinity nerve growth factor receptor (NGFR), which have decreased innervation by nociceptive nerve fibers, and transgenic mice expressing nerve growth factor (NGF) from the lung-specific Clara cell secretory protein (CCSP) promoter, which have increased innervation of the airways, were exposed to HDI-BT aerosol and evaluated at various times after exposure. NGFR knockout mice exhibited significantly more, and CCSP-NGF transgenic mice exhibited significantly less injury and inflammation compared with wild-type mice, indicative of a protective effect of nociceptive nerves on the lung following HDI-BT inhalation. Transgenic mice overexpressing the tachykinin 1 receptor (Tacr1) in lung epithelial cells also showed less severe injury and inflammation compared with wild-type mice after HDI-BT exposure, establishing a role for released tachykinins acting through Tacr1 in mediating at least part of the protective effect. Treatment of lung fragments from Tacr1 transgenic mice with the Tacr1 ligand substance P resulted in increased cAMP accumulation, suggesting this compound as a possible signaling mediator of protective effects on the lung following nociceptive nerve stimulation. The results indicate that sensory nerves acting through Tacr1 can exert protective or anti-inflammatory effects in the lung following isocyanate exposure.

On-filter determination of collected wood dust by diffuse reflectance infrared Fourier-transform spectroscopy (DRIFTS).

A new analytical technique based on DRIFTS spectroscopy has been developed for the specific and sensitive determination of size-fractionated wood dust from 37 mm glass fiber filter samples collected with the Respicon sampler. A translational diffuse reflectance apparatus was modified to accept filter samples by incorporating a special filter holder in the sample stage and a clockwork motor to drive the translational stage during infrared scanning, thus providing an average analysis across the filter face. Filter samples were pre-treated with ethyl acetate to uniformly redeposit dust onto the filter and extract potential chemical interferences. Two absorbance maxima (1251 and 1291 cm(-1)), corresponding to the cellulose content of the wood, were suitable for quantitation of wood dust. Analysis of seven species of wood at 1291 cm(-1) showed an equivalent quantitative response for all species except maple. The response at 1251 cm(-1) was more variable across species but more sensitive for the softwoods. There was a statistically significant effect of particle size on the analytical response, so that analytical standards should be matched to the samples in terms of particle size distribution. Analytical limit of detection was approximately 0.08 mg of wood dust per sample with overall precision of about 6%. Comparison of DRIFTS and gravimetric analyses of 51 pure wood dust samples ranging from about 0.2 to 2 mg yielded a slope of 1.08 and r2 equal to 0.9. Other particulate contaminants common in the industrial wood processing industry showed little or no interference with the determination of wood dust by this method.

Effect of platelet-derived growth factor on the development and persistence of asbestos-induced fibroproliferative lung disease.

Platelet-derived growth factor (PDGF) isoforms and PDGF receptor-alpha are upregulated in fibroproliferative lesions in response to asbestos exposure. To examine the functional role of PDGF in asbestos-induced lung disease, we have evaluated the impact of PDGF-B overexpression in the lung on the development of pulmonary fibrosis induced by asbestos inhalation. Transgenic mice expressing PDGF-B from the surfactant protein C promoter and wild-type C57BL/6 mice were exposed to aerosolized chrysotile asbestos fibers via three different exposure regimens: 3 consecutive days to 9 mg/m(3), once a week for 5 weeks to 12 mg/m(3), or once a week for 8 weeks to 11 mg/m(3). The 3-day exposure did not produce fibroproliferative lesions in SPC-PDGFB or wild-type mice, indicating that PDGF expression did not increase susceptibility to a subthreshold dose of asbestos. Transgenic and wild-type mice subjected to the 5-week exposure protocol exhibited similar fibrogenic lesions histologically 48 hours and 8 weeks postexposure, but lungs from transgenic mice had elevated lung hydroxyproline content 8 weeks postexposure relative to wild-type mice. In addition, SPC-PDGFB transgenic mice developed pronounced thickening of arterioles following the 5-week exposure regimen. Mice exposed to asbestos for 8 weeks and examined 10 months later showed pronounced, diffuse fibrotic lesions of terminal bronchioles and alveolar ducts, but no histological differences between transgenic and nontransgenic mice were observed. These results indicated that PDGF-B overexpression can stimulate increased collagen deposition and vascular smooth muscle hyperplasia following asbestos inhalation and that a limited exposure (8 times) to chrysotile aerosol can produce long-lasting fibrotic lesions. The 8-week exposure regimen provides an animal model that encompasses an important aspect of human asbestosis-i.e., persistence of fibrosis for long periods after cessation of asbestos exposure.

An HDI polyisocyanate aerosol exposure system for large-scale animal experiments.

An exposure system that allows large-scale exposure of animals to 1,6-hexamethylene diisocyanate (HDI)-based polyisocyanates at a stable concentration and aerosol size distribution was developed. The HDI polyisocyanate aerosol is generated by nebulizing a solution of a commercial polyisocyanate product dissolved in acetone. The aerosol is delivered with a constant airflow into a horizontal flow chamber. Complete mixing of aerosol in the chamber is ensured by a circulating fan. This method has been used to generate atmospheres containing HDI polyisocyanates at a concentration of 10.46+/-0.23 mg/m(3) over a 5-hour period. The overall mass median aerodynamic equivalent diameter was found to be 1.42 microm with a geometric standard deviation of 1.26. The HDI monomer concentration was 0.15+/-0.04 mg/m(3). The average chamber acetone concentration was determined to be 2481+/-222 ppm (mean+/-standard deviation). Different HDI polyisocyanate concentrations in the chamber can be achieved by altering the concentration of the commercial polyisocyanate product in acetone and the chamber flow rate. The described exposure system will be useful for performing toxicological studies involving HDI polyisocyanates.

Pulmonary toxicity of polymeric hexamethylene diisocyanate aerosols in mice.

The acute pulmonary response of male C57BL/6 mice exposed to respirable polymeric hexamethylene diisocyanate biuret trimer aerosol (HDI-BT), a component of polyurethane spray paints, was examined. Mice were exposed to concentrations of 1 and 10 mg/m(3) HDI-BT for 5 h and were evaluated 6, 18, 42, 90, 186, and 378 h after the end of exposure. Mice exposed to 1 or 10 mg/m(3) HDI-BT exhibited dose-dependent lung function impairment, edema, neutrophilic inflammation, cellular proliferation, and histologic lesions in terminal bronchioles and alveolar ducts. Impairment of pulmonary function, indicated by decreased frequency and increased enhanced pause (Penh), was maximal immediately after exposure and progressively recovered at later time points. Lung weight and lavage fluid protein content peaked at 6 and 18 h after exposure, respectively. Total cells and macrophages recovered in lavage fluid peaked 90 h after exposure. Neutrophils recovered in lavage fluid peaked between 18 and 42 h after exposure. Proliferative lesions, as identified histologically and by bromodeoxyuridine incorporation, were maximal 90 h after exposure. In contrast, no inflammatory cell influx, protein leakage, or lung pathology were observed in mice exposed to 360 ppb HDI monomer vapor. This model will be useful for investigating molecular mechanisms by which HDI-BT causes lung injury, which is known to occur in humans exposed occupationally to this pulmonary toxicant.