| Literature DB >> 32159942 |
Xin Li1, Wanqian Zhang1,2,3, Wenjiao Lin2,3, Hong Qiu4, Yongli Qi1, Xun Ma1, Haiping Qi2,3, Yao He1, Hongjie Zhang1, Jie Qian4, Gui Zhang2,3, Runlin Gao4, Deyuan Zhang2,3, Jiandong Ding1.
Abstract
A biodegradable coronary stent is expected to eliminate the adverse events of an otherwise eternally implanting material after vessel remodeling. Both biocorrodible metals and biodegradable polymers have been tried as the matrix of the new-generation stent. Herein, we utilized a metal-polymer composite material to combine the advantages of the high mechanical strength of metals and the adjustable degradation rate of polymers to prepare the biodegradable stent. After coating polylactide (PLA) on the surface of iron, the degradation of iron was accelerated significantly owing to the decrease of local pH resulting from the hydrolysis of PLA, etc. We implanted the metal-polymer composite stent (MPS) into the porcine artery and examined its degradation in vivo, with the corresponding metal-based stent (MBS) as a control. Microcomputed tomography (micro-CT), coronary angiography (CA), and optical coherence tomography (OCT) were performed to observe the stents and vessels during the animal experiments. The MPS exhibited faster degradation than MBS, and the inflammatory response of MPS was acceptable 12 months after implantation. Additionally, we implanted another MPS after 1-year implantation of the first MPS to investigate the result of the MPS in the second implantation. The feasibility of the biodegradable MPS in second implantation in mammals was also confirmed.Entities:
Keywords: biodegradable coronary stent; cardiovascular disease; metal−polymer composite stent; polylactide; porcine artery model; surface coating
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Year: 2020 PMID: 32159942 DOI: 10.1021/acsami.0c00971
Source DB: PubMed Journal: ACS Appl Mater Interfaces ISSN: 1944-8244 Impact factor: 9.229