Short inhalation exposures of the isolated and perfused rat lung to respirable dry particle aerosols; the detailed pharmacokinetics of budesonide, formoterol, and terbutaline.

There is an increasing interest in using the lung as a route of entry for both local and systemic administration of drugs. However, because adequate technologies have been missing in the preclinical setting, few investigators have addressed the detailed disposition of drugs in the lung following short inhalation exposures to highly concentrated dry powder aerosols. New methods are needed to explore the disposition of drugs after short inhalation exposures, thus mimicking a future clinical use. Our aim was to study the pulmonary disposition of budesonide, formoterol, and terbutaline, which are clinically used for the treatment of bronchial asthma. Using the recently developed DustGun aerosol technology, we exposed by inhalation for approximately 1 min the isolated and perfused rat lung (IPL) to respirable dry particle aerosols of the three drugs at high concentrations. The typical aerosol concentration was 1 mug/mL, and the particle size distribution of the tested substances varied with a MMAD ranging from 2.3 to 5.3 mum. The IPL was perfused in single pass mode and repeated samples of the perfusate were taken for up to 80 min postexposure. The concentration of drug in perfusate and in lung extracts was measured using LC-MS/MS. The deposited dose was determined by adding the amounts of drug collected in perfusate to the amount extracted from the tissues at 80 min. Deposited amounts of budesonide, formoterol fumarate, and terbutaline sulphate were 23 +/- 17, 36 +/- 8, and 60 +/- 3.2 mug (mean +/- SD, n = 3), respectively. Retention in lung tissues at the end of the perfusion period expressed as fraction of deposited dose was 0.19 +/- 0.05, 0.19 +/- 0.06, and 0.04 +/- 0.01 (mean +/- SD, n = 3) for budesonide, formoterol, and terbutaline, respectively. Each short inhalation exposure to the highly concentrated aerosols consumed 1-3 mg powder. Hence, this system can be particularly useful for obtaining a detailed pharmacokinetic characterization of inhaled compounds in drug discovery/development.

Increasing exposure levels cause an abrupt change in the absorption and metabolism of acutely inhaled benzo(a)pyrene in the isolated, ventilated, and perfused lung of the rat.

The carcinogenic polycyclic aromatic hydrocarbons (PAHs) are active primarily at the site of entry to the body. Lung cancer following inhalation of PAH-containing aerosols such as tobacco smoke is one likely example. A suggested mechanism for this site preference is a slow passage of the highly lipophilic PAHs through the thicker epithelia of the conducting airways, accompanied by substantial local metabolism in airway epithelium. However, it is likely that the airway epithelium will become saturated with PAHs at surprisingly low exposure levels. The purpose of this research was to quantify the level of saturation for inhaled benzo(a)pyrene (BaP) in the isolated, perfused lung (IPL) of the rat. BaP was coated onto carrier particles of silica 3.5 microm diameter at three different levels. The DustGun aerosol generator was then used to deliver respectively 2.2, 36, and 8400 ng of BaP to the IPL with the carrier particles in less than 1 min. For 77 min after the exposure, single-pass perfusate was collected from the lungs. Lungs were then removed and, with the perfusate, analyzed for BaP and metabolites. Results show that the absorption and metabolism of inhaled BaP in the lungs was highly dose dependent. At low exposure levels absorption of BaP in the mucosa was proportional to the concentration in the air/blood barrier and proceeded with substantial local metabolism. At higher exposure levels the capacity of the epithelium to dissolve and metabolize BaP became saturated, and the absorption rate remained constant until crystalline BaP had dissolved, and the process proceeded with much smaller fractions of BaP metabolites produced in the mucosa. This phenomenon may explain the well-known difficulties of inducing lung cancer in laboratory animals with inhalants containing carcinogenic PAHs, where similar lifespan exposures are used as humans may experience but with much higher dose rates.