Investigation of the transporting behavior of framework DNA nano-devices across the artificial Blood-Brain Barrier (BBB)

This study focused on exploring the ability of self-assembled DNA frameworks to cross the blood-brain barrier (BBB). We designed and assembled a series of DNA origami structures with equal quantity of nucleic acid materials but different morphologies and rigidities, such as barrel, soccer ball, icosahedron, and compared their transport efficiency in an in vitro BBB model. It was observed that the relatively large and soft structures could better penetrate the BBB through a lysosome irrelative transcytosis process, while the smallest and most rigid structure was blocked severally accompanied with an obvious lysosome digestion once internalized by the endothelial cells.

DNA Soccer-Ball Framework Templated Liposome Formation with Precisely Regulated Nucleation Seeds

A soccer-ball-shaped three-dimensional DNA origami framework was assembled to serve as an exoskeleton and to direct liposome growth inside. With up to 90 available inner modification sites, cholesterol moieties were introduced as nucleation seeds, and the vesicle templating efficiency was systematically investigated with precisely regulated seed numbers and arrangements. We confirmed that a nonsaturated optimum number (n = 30) of nucleation seeds with relatively even spatial distribution was essential for achieving well-templated and highly uniform liposomes. The seed arrangement principles and effects and the liposome formation mechanisms are thoroughly discussed. The revealed key factors in the design and optimization of 3D DNA nanoframes for functional liposome production could benefit the fields of nanotechnology and molecular medicine.