BACKGROUND: Polycation (PC, polyplex), cationic lipid (CL, lipoplex), and a combination of PC/CL (lipopolyplex) formulations were investigated for gene transfer to slow-proliferating human colon carcinoma cell lines (COGA). METHODS: The luciferase reporter gene was complexed with either PC, CL, or PC/CL. PCs included linear (PEI22lin, 22 kDa) and branched polyethylenimine (PEI2k, 2 kDa; PEI25br, 25 kDa) and poly-L-lysine (PLL18 with 18 lysine monomers). CLs included DOCSPER, DOSPER and DOTAP. Lipopolyplexes were formed by either sequentially first mixing DNA with PC or CL, followed by addition of CL or PC, respectively, or simultaneously with both PC and CL. Particle size and zeta-potential were determined and gene transfer and cytotoxicity were quantified on COGA-3, -5, -12, HeLa and Sw480 cells. RESULTS: The highest gene transfer was achieved when DNA was first complexed with PC followed by CL. At low ionic strength, particles were small (50-130 nm) with a zeta-potential of +20-40 mV. At physiological ionic strength, only lipoplexes of DOCSPER or DOSPER and their respective lipopolyplexes with PEI25br were stable to aggregation (140-220 nm). Lipopolyplexes of PEI25br were between 5- to 400-fold more efficient compared to the corresponding lipoplexes or polyplexes in all cases. Chloroquine did not significantly affect lipopolyplex-mediated gene transfer. CONCLUSIONS: Lipopolyplex formulations of PEI25br in combination with multivalent CLs (DOCSPER, DOSPER) are promising tools for in vitro and potentially also in vivo gene transfer to colorectal cancer cells. Copyright 2005 John Wiley & Sons, Ltd.
BACKGROUND: Polycation (PC, polyplex), cationic lipid (CL, lipoplex), and a combination of PC/CL (lipopolyplex) formulations were investigated for gene transfer to slow-proliferating humancolon carcinoma cell lines (COGA). METHODS: The luciferase reporter gene was complexed with either PC, CL, or PC/CL. PCs included linear (PEI22lin, 22 kDa) and branched polyethylenimine (PEI2k, 2 kDa; PEI25br, 25 kDa) and poly-L-lysine (PLL18 with 18 lysine monomers). CLs included DOCSPER, DOSPER and DOTAP. Lipopolyplexes were formed by either sequentially first mixing DNA with PC or CL, followed by addition of CL or PC, respectively, or simultaneously with both PC and CL. Particle size and zeta-potential were determined and gene transfer and cytotoxicity were quantified on COGA-3, -5, -12, HeLa and Sw480 cells. RESULTS: The highest gene transfer was achieved when DNA was first complexed with PC followed by CL. At low ionic strength, particles were small (50-130 nm) with a zeta-potential of +20-40 mV. At physiological ionic strength, only lipoplexes of DOCSPER or DOSPER and their respective lipopolyplexes with PEI25br were stable to aggregation (140-220 nm). Lipopolyplexes of PEI25br were between 5- to 400-fold more efficient compared to the corresponding lipoplexes or polyplexes in all cases. Chloroquine did not significantly affect lipopolyplex-mediated gene transfer. CONCLUSIONS:Lipopolyplex formulations of PEI25br in combination with multivalent CLs (DOCSPER, DOSPER) are promising tools for in vitro and potentially also in vivo gene transfer to colorectal cancer cells. Copyright 2005 John Wiley & Sons, Ltd.
Authors: Elina Vuorimaa; Tiia-Maaria Ketola; Jordan J Green; Martina Hanzlíková; Helge Lemmetyinen; Robert Langer; Daniel G Anderson; Arto Urtti; Marjo Yliperttula Journal: J Control Release Date: 2011-06-15 Impact factor: 9.776
Authors: Maung T Nyunt; Christopher W Dicus; Yi-Yao Cui; M Cecilia Yappert; Thomas R Huser; Michael H Nantz; Jian Wu Journal: Bioconjug Chem Date: 2009-11 Impact factor: 4.774