Continuous flow production of cationic liposomes at high lipid concentration in microfluidic devices for gene delivery applications

Microfluidics is a powerful technology that allows the production of cationic liposomes by the hydrodynamic focusing method. We first studied a single hydrodynamic focusing (SHF) device, which uses a central stream in which lipids dispersed in ethanol are injected and hydrodynamically compressed by the two aqueous streams. The ethanol diffusion from the inner stream to the aqueous stream encourages the formation of the liposomes. To intensify the mass diffusion and increase the surface area between the two fluids, a second device was designed with double hydrodynamic focusing (DHF). We investigated the influence of fluid flow velocity (Vf), Flow Rate Ratio (FRR) and total lipid concentration (Clip) on the particle size of the CLs produced. The DHF microfluidic device had the ability of using higher Vf values than the SHF device, which resulted in a higher productivity level. Small Angle X-ray Scattering (SAXS) experiments were performed to structurally characterize the cationic liposomes produced by both microfluidic devices. The SAXS results revealed that both devices produce unilamellar cationic liposomes with a very small fraction of multilamellar liposomes; this finding is in agreement with the observations made in the analysis of the liposomes using Transmission Electron Microscopy (TEM). The biological efficacies of the cationic liposomes produced by both microfluidic devices were examined in vitro in HeLa cells, which confirmed their potential for gene delivery and vaccine therapy applications.

[1]  H. Herweijer,et al.  Gene therapy progress and prospects: Hydrodynamic gene delivery , 2007, Gene Therapy.

[2]  José Alberto Fracassi da Silva,et al.  Fabrication of a multichannel PDMS/glass analytical microsystem with integrated electrodes for amperometric detection. , 2009, Lab on a chip.

[3]  Wyatt N Vreeland,et al.  Controlled vesicle self-assembly in microfluidic channels with hydrodynamic focusing. , 2004, Journal of the American Chemical Society.

[4]  D. Prazeres,et al.  Development of a recombinant fusion protein based on the dynein light chain LC8 for non-viral gene delivery. , 2012, Journal of controlled release : official journal of the Controlled Release Society.

[5]  R. Kumar,et al.  Enhanced gene delivery and mechanism studies with a novel series of cationic lipid formulations. , 1994, The Journal of biological chemistry.

[6]  Junxian Yun,et al.  Formation of solid lipid nanoparticles in a microchannel system with a cross-shaped junction , 2008 .

[7]  Bo Yu,et al.  Microfluidic methods for production of liposomes. , 2009, Methods in enzymology.

[8]  Jaesung Park,et al.  Formation of liposomes using a 3D flow focusing microfluidic device with spatially patterned wettability by corona discharge , 2012 .

[9]  M. H. Santana,et al.  Surface miscibility of EPC/DOTAP/DOPE in binary and ternary mixed monolayers. , 2011, Colloids and Surfaces B: Biointerfaces.

[10]  M. Takinoue,et al.  Droplet microfluidics for the study of artificial cells , 2011, Analytical and bioanalytical chemistry.

[11]  D. Roux,et al.  Effect of shear on a lyotropic lamellar phase , 1993 .

[12]  D. Lasič,et al.  Liposomes: From Physics to Applications , 1993 .

[13]  Guido Marcucci,et al.  Delivery of antisense oligodeoxyribonucleotide lipopolyplex nanoparticles assembled by microfluidic hydrodynamic focusing. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[14]  R. Adrian,et al.  Transition from laminar to turbulent flow in liquid filled microtubes , 2004 .

[15]  S. Ramos,et al.  Protection against tuberculosis by a single intranasal administration of DNA-hsp65 vaccine complexed with cationic liposomes , 2008, BMC Immunology.

[16]  Peng George Wang,et al.  A facile microfluidic method for production of liposomes. , 2008, Anticancer research.

[17]  Wyatt N Vreeland,et al.  Microfluidic mixing and the formation of nanoscale lipid vesicles. , 2010, ACS nano.

[18]  R. Ofoli,et al.  Comparison of liposomes formed by sonication and extrusion: rotational and translational diffusion of an embedded chromophore. , 2007, Langmuir : the ACS journal of surfaces and colloids.

[19]  Paul A Dayton,et al.  Microfluidic generation of acoustically active nanodroplets. , 2012, Small.

[20]  Justin M. Zook,et al.  Effects of temperature, acyl chain length, and flow-rate ratio on liposome formation and size in a microfluidic hydrodynamic focusing device , 2010 .

[21]  M. H. Santana,et al.  The synergy between structural stability and DNA-binding controls the antibody production in EPC/DOTAP/DOPE liposomes and DOTAP/DOPE lipoplexes. , 2009, Colloids and surfaces. B, Biointerfaces.

[22]  Do Hyun Kim,et al.  Formation of liposome by microfluidic flow focusing and its application in gene delivery , 2012, Korea-Australia Rheology Journal.

[23]  C. L. Oliveira,et al.  Correlation of the physicochemical and structural properties of pDNA/cationic liposome complexes with their in vitro transfection. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[24]  A. Vila,et al.  Influence of the electrical interface properties on the rheological behavior of sonicated soy lecithin dispersions. , 2007, Journal of colloid and interface science.

[25]  G. Maulucci,et al.  Particle size distribution in DMPC vesicles solutions undergoing different sonication times. , 2005, Biophysical journal.

[26]  J. Sotolongo,et al.  Preparation of plasmid DNA-containing liposomes using a high-pressure homogenization--extrusion technique. , 2005, Journal of controlled release : official journal of the Controlled Release Society.

[27]  L. J. Lee,et al.  Ultrasound-enhanced microfluidic synthesis of liposomes. , 2010, Anticancer research.

[28]  S. Takeuchi,et al.  Generation of lipid vesicles using microfluidic T-junctions with pneumatic valves , 2010, 2010 IEEE 23rd International Conference on Micro Electro Mechanical Systems (MEMS).

[29]  M. H. Santana,et al.  Technological Aspects of Scalable Processes for the Production of Functional Liposomes for Gene Therapy , 2011 .

[30]  G. Whitesides The origins and the future of microfluidics , 2006, Nature.

[31]  Stephanie E. A. Gratton,et al.  The effect of particle design on cellular internalization pathways , 2008, Proceedings of the National Academy of Sciences.

[32]  M. C. Ruzicka,et al.  On dimensionless numbers , 2008 .

[33]  M. H. Santana,et al.  Effectiveness, against tuberculosis, of pseudo-ternary complexes: peptide-DNA-cationic liposome. , 2012, Journal of colloid and interface science.

[34]  M. R. Mozafari,et al.  Liposomes: an overview of manufacturing techniques. , 2005, Cellular & molecular biology letters.

[35]  Wyatt N Vreeland,et al.  Microfluidic directed formation of liposomes of controlled size. , 2007, Langmuir : the ACS journal of surfaces and colloids.

[36]  M. H. Santana,et al.  Effects of extrusion, lipid concentration and purity on physico-chemical and biological properties of cationic liposomes for gene vaccine applications , 2012, Journal of microencapsulation.

[37]  F. Dehghani,et al.  Conventional and Dense Gas Techniques for the Production of Liposomes: A Review , 2008, AAPS PharmSciTech.

[38]  Daniel A. Balazs,et al.  Liposomes for Use in Gene Delivery , 2010, Journal of drug delivery.

[39]  Wyatt N Vreeland,et al.  Controlled self-assembly of monodisperse niosomes by microfluidic hydrodynamic focusing. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[40]  E. Staples,et al.  Effects of Shear on the Lamellar Phase of a Dialkyl Cationic Surfactant , 2001 .