Bulk and Microfluidic Synthesis of Stealth and Cationic Liposomes for Gene Delivery Applications.

This chapter describes the synthesis of stealth and cationic liposomes and their complexation with plasmid DNA to generate lipoplexes for gene delivery applications. Two techniques are presented: a top-down approach which requires a second step of processing for downsizing the liposomes (i.e., ethanol injection method) and a microfluidic technique that explores the diffusion of ethanol in water to allow the proper lipid self-assembly. The synthesis of stealth liposomes is also a challenge since the use of poly(ethylene glycol) favors the formation of oblate micelles. In this protocol, the stealth cationic liposome synthesis by exploring the high ionic strength to overcome the formation of secondary structures like micelles is described. Finally, the electrostatic complexation between cationic liposomes and DNA is described, indicating important aspects that guarantee the formation of uniform lipoplexes.

Ionic strength for tailoring the synthesis of monomodal stealth cationic liposomes in microfluidic devices.

In this work, we describe a hydrodynamic flow-focusing microfluidic process to produce stealth cationic liposomes (SCL), stabilized with poly(ethylene glycol) (PEG), with uniform and reproducible features. Through cryogenic transmission electron microscopy (cryo-TEM) characterization and real-time monitoring, we verified the formation of multi-sized lipid self-aggregates, which can be attributed to micelles formation. These structures tend to undergo deposition within the PDMS/glass microchannels through intermolecular interactions with the glass walls, hindering not only the process reproducibility but also the final biological application of the SCL products. In view of this, we propose the modulation of ionic strength of the side streams aiming to ionically shield the glass surface, decrease the intermolecular interactions of the lipid polar heads, and, essentially, to promote the bilayer-driven self-assembly of SCL with 1% of DSPE-PEG2000 lipid. Herein, we applied phosphate-buffered saline (PBS) from 10 to 50 mM concentration as side streams, and evaluated its effects on SCL final physicochemical properties in terms of size distribution, mean diameter, zeta potential and polydispersity index (PDI). We present evidences indicating that the ionic strength can be used as a microfluidic process parameter to modulate the lipids self-assembly kinetics whilst preventing micelles formation. Finally, the proposed diffusion-based microfluidic system with high ionic strength enables the formation of monodisperse (PDI < 0.2) SCL of around 140 nm with monomodal size distributions and enhanced properties when compared to usual bulk mixing.