Microfluidics-Directed Self-Assembly of DNA-Based Nanoparticles

The 'bottom-up' paradigm of nanofabrication mostly relies on molecular self-assembly, a process by which individual components spontaneously form ordered structures with emerging functions. Soft nanoparticles made up of therapeutic DNA condensed by cationic lipids or surfactants hold a great potential for nonviral gene delivery. Their self-assembly is driven by strong electrostatic interactions. As a consequence, nanoparticles formulated in bulk often exhibit broad size distributions not suitable for practical delivery applications. We will review the recent strategies we developed to control the self-assembly kinetics by using microfluidic devices. This combined approach may open attractive opportunities for the directed self-assembly of complex soft nanomaterials in particular for biomedical purposes.