Effects of paclitaxel[poly(L-lactide)/plyglycolide] degradable material on human umbilical arterial smooth muscle cells
- VernacularTitle:紫杉醇可降解乙交酯/丙交酯共聚物材料对人脐动脉平滑肌细胞的作用
- Author:
Xiaonan HE
;
Yu CHEN
;
Chen CHEN
;
Haishan YANG
- Publication Type:Journal Article
- From:
Chinese Journal of Tissue Engineering Research
2008;12(41):8175-8178
- CountryChina
- Language:Chinese
-
Abstract:
BACKGROUND:High-incidence early acute reocculision and later restenosis following coronary artery stenting has been widely studied.Biodegradable material metal coated stent carrying paclitaxel,which can effectively inhibit restenosis,is promising for solving this problem.OBJECTIVE:To evaluate the effects of paclitaxel containing degradable material [poly (L-lactide) (PLLA)/polyglyoolide(PGA)]on human umbilical arterial smooth muscle cells.DESIGN,TIME AND SETTING:The present controlled observational cytological experiment was performed at the Laboratory of Toxicity,College of Public Health,Jilin University between July 2003 and July 2005.MATERIALS:Paclitaxel (PLLA/PGA) (PLLA:PGA=9:1) was provided by the Changchun Institute of Applied Chemistry,China.METHODS:The primary human umbilical arterial smooth muscle cells were cultured for passage cells.Thereafter,passage cells were co-cultured with degradable materials containing different concentrations of paclitaxel (1,2,and 3 g).Mental stent and paclitaxel-free PLLA/PGA were used for controls.MAIN OUTCOME MEASURES:At 0,24,48,and 72 hours after culture,effects of degradable materials containing different concentrations of paclitaxel on smooth muscle cell growth were observed under a contrast microscope.RESULTS:Mental stent and paclitaxel-free PLLA/PGA had no influences on smooth muscle cell growth.Paclitaxel(PLLA/PGA) degradable material (1,2,and 3 paclitaxel) inhibited smooth muscle cell growth till 72 hours.There were significant differences between mental stent and paclitaxel-free PLLA/PGA and paxlitaxel(PLLA/PGA) groups (P<0.01).CONCLUSION:Paclitaxel (PLLA/PGA) degradable material can be used as the intravascular stenting material for inhibiting smooth muscle cell growth.
