posted on 2019-07-22, 14:13authored byCassidy
C. Dolstra, Torri Rinker, Shalene Sankhagowit, Sarah Deng, Christina Ting, Amanda T. Dang, Tonya L. Kuhl, Darryl Y. Sasaki
Lipid
bilayer-coated mesoporous silica nanoparticles are unique
core–shell nanomaterials currently being developed as drug
delivery vehicles. To improve cargo loading and biocirculation, the
pore structure and surface chemistry of the particle have been modified
and well characterized. However, an understanding of cargo release
mechanisms from cellular uptake pathways remains largely unexplored.
Here, we present a study of the release mechanism of lipid bilayer-coated
silica particles induced by endosomal-like pH change from 7.4 to 5.0.
We found that this relatively small pH change produces rapid deformation
of the supported lipid bilayer that ultimately results in holes in
the membrane. Using a combination of dye release studies, wide-field
and confocal fluorescence microscopies, and surface area modeling
analysis, we determined that small blister-like structures are formed,
which lead to lateral membrane displacement and hole formation. Possible
mechanisms for the blister formation, which include curvature effects
and interfacial interactions, are discussed.