HYPOTHESIS Fluorocarbon gases introduced above monolayers of phospholipids at the air/water interface were recently found to promote the adsorption of diverse molecular compounds, with potential application in drug-loaded microbubble design.… Click to show full abstract
HYPOTHESIS Fluorocarbon gases introduced above monolayers of phospholipids at the air/water interface were recently found to promote the adsorption of diverse molecular compounds, with potential application in drug-loaded microbubble design. Quantitative determination of the fluorocarbon present in the monolayers is strongly needed for the development of such applications. We hypothesized that neutron reflectometry (NR) and ellipsometry experiments would allow quantification of the fluorocarbon trapped in the monolayers. EXPERIMENTS We report the first quantitative determination of the extents of adsorption of perfluorohexane (F-hexane) on different phospholipid monolayers with respect to both their phase and isotopic form. To this aim, we applied an approach based on co-modeling the data obtained from NR and ellipsometry. FINDINGS We found that F-hexane adsorbs strongly in monolayers of dipalmitoylphosphatidylcholine (DPPC) when they are both in the liquid expanded (LE) and liquid condensed (LC) phases, but to different extents according to the isotopic form of the phospholipid. Kinetic resolution of the interfacial composition from data on both isotopic contrasts (assuming chemical identicality) was therefore not possible using NR alone, so an alternative NR/ellipsometry co-modeling treatment was applied to data from each isotopic contrast. F-hexane adsorbs more abundantly on monolayers of hydrogenous DPPC than chain-deuterated DPPC when they are in the LE phase, whilst the opposite was observed when they monolayers are in the LC phase. The extents of adsorption of F-hexane in monolayers of dimyristoylphosphatidylcholine (DMPC, LE phase) and distearoylphosphatidylcholine (DSPC, LC phase) concurs with the strong dependence of those with phospholipids of different isotopic contrasts according to the monolayer phase. This new methodology can lead to advances in the novel characterization of fluorocarbons interacting with phospholipid monolayers of relevance to applications such as in the shells of fluorocarbon-stabilized medically-oriented microbubbles.
               
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