In vitro gene transfection by magnetic iron oxide nanoparticles and magnetic field increases transfection efficiency.
- Author:
Juan-juan XIANG
1
;
Xin-min NIE
;
Jing-qun TANG
;
Yan-jin WANG
;
Zheng LI
;
Kai GAN
;
He HUANG
;
Wei XIONG
;
Xiao-ling LI
;
Gui-yuan LI
Author Information
- Publication Type:Journal Article
- MeSH: Animals; COS Cells; Ferric Compounds; administration & dosage; Genetic Vectors; Magnetics; Polylysine; administration & dosage; Transfection; methods
- From: Chinese Journal of Oncology 2004;26(2):71-74
- CountryChina
- Language:Chinese
-
Abstract:
OBJECTIVETo evaluate the feasibility of using iron oxide nanoparticles as gene vector and the effect of magnetic field on efficiency of transfection.
METHODSIron oxide nanoparticles were prepared by alkaline precipitation of divalent and trivalent iron chloride. The surface of iron oxide nanoparticles was modified by self-assembled poly-L-lysine to form particle complexes (IONP-PLL). Transfection was determined by delivering reporter gene, PGL2-control encoding luciferase, to different cell lines using IONP-PLL as vector. The effect of magnetic field on efficiency of transfection was determined using Nd-Fe-B permanent magnet.
RESULTSForeign gene could be delivered to various cell lines by IONP-PLL and expressed with high efficiency, but the transfection efficiency and time course varied in the different cell lines studied. Magnetic field could enhance the efficiency of transfection by 5 - 10 fold.
CONCLUSIONIONP-PLL can be used as a novel non-viral gene vector in vitro, which offers a basis for gene delivery in vivo.
