Quantitative study of effects of free cationic chains on gene transfection in different intracellular stages.

Previously, we revealed that in the application of using cationic polymer chains, polyethylenimine (PEI), to condense anionic plasmid DNA chains (pDNA) to form the DNA/polymer polyplexes, after all the pDNAs are complexed with PEI, further added PEIs exist individual chains and free in the solution mixture. It is those uncomplexed polycation chains that dramatically promote the gene transfection. In the current study, we studied how those free cationic chains with different lengths and topologies affect the intracellular trafficking of the polyplexes, the translocation of pDNA through the nuclear membrane, the transcription of pDNA to mRNA and the translocation of mRNA from nucleus to cytosol in HepG2 cells by using a combination of the three-dimensional confocal microscope and TaqMan real-time PCR.

Investigation of cell behaviors on thermo-responsive PNIPAM microgel films.

The use of poly(N-isopropylacrylamide) (PNIPAM) as building blocks for engineering responsive coatings and their potential use as switchable substrates such as biosensors have attracted great attention in recent years. However, few studies have been conducted regarding the cell behaviors and the related mechanism on thermos-responsive surfaces consisting of PNIPAM microgel particles. In this work, monodisperse PNIPAM microgels were synthesized and used to prepare PINPAM microgel films.

One-step formation of w/o/w multiple emulsions stabilized by single amphiphilic block copolymers.

Multiple emulsions are complex polydispersed systems in which both oil-in-water (O/W) and water-in-oil (W/O) emulsion exists simultaneously. They are often prepared accroding to a two-step process and commonly stabilized using a combination of hydrophilic and hydrophobic surfactants. Recently, some reports have shown that multiple emulsions can also be produced through one-step method with simultaneous occurrence of catastrophic and transitional phase inversions.

Revisit complexation between DNA and polyethylenimine--effect of length of free polycationic chains on gene transfection.

Our revisit of the complexation between DNA and polyethylenimine (PEI) by using a combination of laser light scattering and gel electrophoresis confirms that nearly all the DNA chains are complexed with PEI to form polyplexes when the molar ratio of nitrogen from PEI to phosphate from DNA (N:P) reaches ~3, irrespective of the PEI chain length and solvent. Each solution mixture with N:P>3 contains two kinds of PEI chains: bound to DNA and free in the solution. It has been shown that it is those free PEI chains that play a vital role in promoting the gene transfection.

Revisit complexation between DNA and polyethylenimine - Effect of uncomplexed chains free in the solution mixture on gene transfection.

Our revisit of the complexation between anionic DNA and cationic polyethylenimine (PEI) in both water and phosphate buffered saline (PBS) by using a combination of laser light scattering (LLS) and gel electrophoresis confirms that nearly all the DNA chains are complexed with PEI to form polyplexes when the molar ratio of nitrogen from PEI to phosphate from DNA (N:P) reaches ~3, but the PEI/DNA polyplexes have a high in-vitro gene transfection efficiency only when N:P≥10. Putting these two facts together, we not only conclude that this extra 7 portions of PEI chains are free in the solution mixture, but also confirmed that it is these free PEI chains that substantially promote the gene transfection no matter whether they are applied hours before or after the administration of the much less effective PEI/DNA polyplexes (N:P=3). The uptake kinetics measured by flow cytometry shows that the addition of free PEI leads to a faster and more efficient cellular internalization of polyplexes, but these free PEI chains mainly contribute to the subsequent intracellular trafficking.