Bile salt enhancers for inhalation: Correlation between in vitro and in vivo lung effects.

The lungs have potential as a means of systemic drug delivery of macromolecules. Systemic delivery requires crossing of the air-blood barrier, however with molecular size-dependent limitations in lung absorption of large molecules. Systemic availability after inhalation can be improved by absorption enhancers, such as bile salts. Enhancers may potentially interfere with the different constituents of the lungs, e.g. the lung surfactant lining the alveoli or the lung epithelium. We used two in vitro models to investigate the potential effects of bile salts on lung surfactant function (with the constrained drop surfactometer) and on the epithelium in the proximal airways (with the MucilAir™ cell system), respectively. In addition, we measured direct effects on respiration in mice inhaling bile salt aerosols. The bile salts inhibited lung surfactant function at different dose levels, however they did not affect the integrity of ciliated cells at the tested doses. Furthermore, the bile salt aerosols induced changes in the breathing pattern of mice indicative of pulmonary irritation. The bile salts were ranked according to potency in vitro for surfactant function disruption and in vivo for induction of pulmonary irritation. The ranking was the same, suggesting a correlation between the interference with lung surfactant and the respiratory response.

Multi-walled carbon nanotube-physicochemical properties predict the systemic acute phase response following pulmonary exposure in mice.

Pulmonary exposure to multi-walled carbon nanotubes (MWCNTs) has been linked to an increased risk of developing cardiovascular disease in addition to the well-documented physicochemical-dependent adverse lung effects. A proposed mechanism is through a strong and sustained pulmonary secretion of acute phase proteins to the blood. We identified physicochemical determinants of MWCNT-induced systemic acute phase response by analyzing effects of pulmonary exposure to 14 commercial, well-characterized MWCNTs in female C57BL/6J mice pulmonary exposed to 0, 6, 18 or 54 µg MWCNT/mouse. Plasma levels of acute phase response proteins serum amyloid A1/2 (SAA1/2) and SAA3 were determined on day 1, 28 or 92. Expression levels of hepatic Saa1 and pulmonary Saa3 mRNA levels were assessed to determine the origin of the acute phase response proteins. Pulmonary Saa3 mRNA expression levels were greater and lasted longer than hepatic Saa1 mRNA expression. Plasma SAA1/2 and SAA3 protein levels were related to time and physicochemical properties using adjusted, multiple regression analyses. SAA3 and SAA1/2 plasma protein levels were increased after exposure to almost all of the MWCNTs on day 1, whereas limited changes were observed on day 28 and 92. SAA1/2 and SAA3 protein levels did not correlate and only SAA3 protein levels correlated with neutrophil influx. The multiple regression analyses revealed a protective effect of MWCNT length on SAA1/2 protein level on day 1, such that a longer length resulted in lowered SAA1/2 plasma levels. Increased SAA3 protein levels were positively related to dose and content of Mn, Mg and Co on day 1, whereas oxidation and diameter of the MWCNTs were protective on day 28 and 92, respectively. The results of this study reveal very differently controlled pulmonary and hepatic acute phase responses after MWCNT exposure. As the responses were influenced by the physicochemical properties of the MWCNTs, this study provides the first step towards designing MWCNT that induce less SAA.