posted on 2018-07-09, 00:00authored byYan Xu, Shixin Li, Zhen Luo, Hao Ren, Xianren Zhang, Fang Huang, Yi Y. Zuo, Tongtao Yue
Hydrophilic drugs can be delivered into lungs via nebulization
for both local and systemic therapies. Once inhaled, ultrafine nanodroplets
preferentially deposit in the alveolar region, where they first interact
with the pulmonary surfactant (PS) layer, with nature of the interaction
determining both efficiency of the pulmonary drug delivery and extent
of the PS perturbation. Here, we demonstrate by molecular dynamics
simulations the transport of nanodroplets across the PS layer being
improved by lipid coating. In the absence of lipids, bare nanodroplets
deposit at the PS layer to release drugs that can be directly translocated
across the PS layer. The translocation is quicker under higher surface
tensions but at the cost of opening pores that disrupt the ultrastructure
of the PS layer. When the PS layer is compressed to lower surface
tensions, the nanodroplet prompts collapse of the PS layer to induce
severe PS perturbation. By coating the nanodroplet with lipids, the
disturbance of the nanodroplet on the PS layer can be reduced. Moreover,
the lipid-coated nanodroplet can be readily wrapped by the PS layer
to form vesicular structures, which are expected to fuse with the
cell membrane to release drugs into secondary organs. Properties of
drug bioavailability, controlled drug release, and enzymatic tolerance
in real systems could be improved by lipid coating on nanodroplets.
Our results provide useful guidelines for the molecular design of
nanodroplets as carriers for the pulmonary drug delivery.