Vesicle-like structure of lipid-based nanoparticles as drug delivery system revealed by molecular dynamics simulations
Maryam Khalkhali, Sarah Mohammadinejad, Farhad Khoeini, Kobra, Rostamizadeh

TL;DR
This study used molecular dynamics simulations to reveal vesicle-like nanostructures in lipid-based drug delivery systems, showing lipid organization and water entrapment within nanoparticles of about 12 nm diameter.
Contribution
It provides detailed molecular insights into the nanostructure and lipid distribution of lipid-based nanoparticles, including the impact of solid to liquid lipid ratios, using coarse-grained MD simulations.
Findings
Vesicle-like structures observed in all lipid nanoparticles studied.
Water entrapment within the lipid droplets was identified.
Lipid density varies between nanoemulsions, SLN, and NLC systems.
Abstract
Lipid-based drug delivery systems are considered as promising vehicles for hydrophobic drug compounds. Lipid distribution within the droplet can affect drug loading capacity in these carriers. It is extremely challenging to determine the nanostructure within these carriers through the implementation of the direct experimental methods due to the ultrafine size. Therefore, coarse grained molecular dynamics (MD) simulation was utilized to model different lipid-based nanoparticles of the diameter about 12 nm including solid lipid nanoparticles (SLN), nanoemulsion (NE), and nanostructured lipid carriers (NLC), and the organization of the lipids within the carriers was explored. The aforementioned nanoparticles consisted of stearic acid, oleic acid as lipids, and sodium dodecyl sulfate (SDS) as a surfactant in water medium. Furthermore, the impact of solid to liquid mass ratio on the lipid…
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