To evaluate the possibility and efficiency of nanoparticle as a new vector in specific gene transference.Methods. Nanoparticle-DNA complex was prepared with Poly- eM-lactic-co-glycolic acid (PLGA) bearing anti-sense monocyte chemotactic protein-1 (A-MCP-1), a specific expression gene, and the package efficiency, release progress in vitro, and the size of the complex were determined. The possibility of the new vector was evaluated with genomic DNA PCR by transferring gene into cultured smooth muscle cells (SMC), cationic lipids as a control. For study in vivo, jugular vein-to-artery bypass grafting procedures were performed on 20 New Zealand white rabbits, of which 6 grafts were transferred with nanoparticle-A-MCP-1 (200 μg), 6 with A - MCP - 1 (200 μ g) by cationic liposome, 4 with LNCX plasmid, and 4 as control. Fourteen days after the grafts were harvested, the expression of A-MCP-1 and its effect on MCP-1 in vein grafts were detected by dot blot, and the morphologic evaluation of grafts was performe To evaluate the possibility and efficiency of nanoparticle as a new vector in specific gene transference. Methods. Nanoparticle-DNA complex was prepared with Poly-eM-lactic-co-glycolic acid (PLGA) bearing anti-sense monocyte chemotactic protein-1 -MCP-1), a specific expression gene, and the package efficiency, release progress in vitro, and the size of the complex were determined. The possibility of the new vector was evaluated with genomic DNA PCR by transferring gene into cultured smooth muscle cells (SMC), cationic lipids as a control. For study in vivo, jugular vein-to-artery bypass grafting procedures were performed on 20 New Zealand white rabbits, of which 6 grafts were transferred with nanoparticle-A-MCP- ), With A-MCP-1 (200 μg) by cationic liposome, 4 with LNCX plasmid, and 4 as control. Fourteen days after the grafts were harvested, the expression of A-MCP-1 and its effect on MCP- 1 in vein grafts were detected by dot blot, and the morphologic evaluation of grafts was performe