In this research, we modified chitosan, the non-viral vector, with different degrees of biotin moieties. By electrostatic interaction, we prepared self-assemble nanoparticles using biotinylated-chitosan and plasmid DNA in different amine/phosphate ratio. The dynamic laser scattering experiment has demonstrated that particle sizes of biotinylated nanoparticles were between the 66.8 nm to 109.8 nm and the Zeta potential was between 21.6 to 36.0 mV, suggesting that these nanoparticles were suitable for gene delivery. In addition, biotinylated chitosan may effectively bind DNA to protect it from DNase I digestion. The LDH and MTS assays suggested that biotin modification did not only maintain the biocompatibility of chitosan, but also reduce the cytotoxicity. Through the optimatization of biotin-avidin interaction, biotinylated nanoparticles may be immobilized on material surfaces for in situ gene delivery. Compares to bolus gene delivery, our developed in situ gene delivery may enhance the transfection efficiency of 4.5 folds. These results suggest that our strategy successfully improved transfection efficiency of non-viral vectors.