Dosimetry parameters such as deposition, clearance, retention, and translocation and dissolution of inhaled particles in and to different lung compartments may be important for the persistence of particles in the lung and may correlate with adverse pulmonary effects. We investigated such correlations using a model involving TiO2 particles of two particle sizes (20 nm diameter, ultrafine; 250 nm diameter, fine) of the same crystalline structure (anatase). A 12-week inhalation experiment in rats resulted in a similar mass deposition of the two particle types in the lower respiratory tract. The ultrafine particles elicited a persistently high inflammatory reaction in the lungs of the animals compared to the larger-sized particles. In the postexposure period (up to 1 year) retention in the alveolar space per se was not different between fine and ultrafine TiO2. However, the following differences between the particle types were noted: a significantly different total pulmonary retention, both quantitatively (significantly prolonged retention of the ultrafine TiO2) and qualitatively (increased translocation to the pulmonary interstitium and persistence there of the ultrafine TiO2); greater epithelial effects (Type II cell proliferation; occlusion of pores of Kohn) and the beginning of interstitial fibrotic foci with ultrafine TiO2; significant sustained impairment of alveolar macrophage function after ultrafine TiO2 exposure as measured by the clearance of test particles. A correlation between particle surface area and effects was observed. A comparison of the adverse reactions with dosimetric parameters of TiO2 in different lung compartments in the postexposure period showed a correlation of the persistence of effects in both the alveolar and interstitial space with the persistence of particles in the respective compartment.
The increased plasma sCD40L levels support the hypothesis that higher levels of ambient air pollution lead to an inflammatory response in patients with CHD thus providing a possible explanation for the observed association between air pollution and cardiovascular morbidity and mortality in susceptible parts of the population.
Effective elimination of particles deposited in the respiratory tract is an important defense function to protect the organism from potentially adverse effects of inhaled particles. Delivery of radioactively labeled tracer particles and subsequent measurement in vivo of their retention in different regions of the respiratory tract provides an adequate method for characterizing this defensive function. However, the delivery of such tracer particles by inhalation may result in some external contamination of the animals and requires specific protective measures while working with radioactive aerosols. In this study, 85Sr-labeled tracer particles (3 microns) were administered to the lower respiratory tract of rats by intratracheal inhalation to avoid external contamination, and also by intratracheal instillation in order to compare the 2 technique with respect to their suitability for measuring normal and impaired particle clearance rates. It was postulated that particle clearance function in the alveolar region can be determined equally well with intratracheally instilled particles despite their uneven distribution in the lung. For both techniques, rats were anesthesized with halothane and the particles were administered via oral intubation. Retention in the lower respiratory tract of about 30 micrograms (inhalation) and 6 micrograms (instillation) of the administered particles was followed over a period of 180 days by external counting of lung 85Sr-activity in a collimated detection system. To impair alveolar particle clearance rates, groups of rats were subjected to 12 weeks of inhalation exposure prior to delivery of the tracer particles as follows: (1) sham-exposed control; (2) pigment-grade TiO2 particles to induce lung overload: (3) ultrafine TiO2 particles: (4) crystalline SiO2 particles (cristobalite). The following results were obtained: The long-term retention half-times (T1/2) of the tracer particles reflecting alveolar clearance consistently showed the same ranking of the treatment groups whether measured after intratracheal inhalation or instillation. Control values were 66 and 72 days, respectively, and significantly prolonged long-term clearance was measured by both methods for pigment-grade TiO2 (117 and 99 days), ultrafine TiO2 (541 and 600 days) and SiO2 (1901 and 1368 days). Comparison of these values between the two modes of administration of tracer particles showed no significant differences. In contrast, the short-term T1/2 (mucociliary clearance) of the intratracheally instilled tracer particles in the different treatment groups were variable and did not accurately reflect particle clearance from the conducting airways. However, short-term T1/2 after intratracheal inhalation of tracer particles were consistent with fast conducting airway clearance, and mucociliary clearance appears to be stimulated when alveolar clearance is significantly impaired due to particle overload or to effects of cytotoxic particles. The results suggest that intratracheal instillation of a low dose (< or = 10 microgra...
Hygroscopic aerosol particles will grow in the human respiratory tract due to the nearly saturated air. A calculation method had been developed previously to estimate the growth and the deposition in the human respiratory tract of salt particles.This method is adapted here to estimate the growth and the deposition of particles of three drugs during respiration. The relative growth of drug particles is comparable to the growth of salt particles, where different drug particles change their size by a factor of 2.2-3.5, and salt particles by a factor of 2.0-4.4. Likewise, the deposition in the bronchial and pulmonary regions is enhanced for particles with initial sizes in the range of 0.3-5 urn for both the drug and salt particles. The increase in deposition is about a factor of 2 for particles with initial sizes between 0.5-2 urn. Also, the maximum values for deposition in the bronchial and pulmonary regions at initial particle sizes between 2-4 urn are increased by up to 20% compared to the values for stable particles. An equation is proposed to estimate the deposition of an arbitrary aerosolized drug particle in the bronchial and pulmonary regions.We conclude that the hygroscopicity of drug particles is an important factor for estimating their deposition in the human respiratory tract.
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