表面处理对形状记忆NiTi支架生物反应影响的初步研究。

C Trépanier, T K Leung, M Tabrizian, L H Yahia, J G Bienvenu, J F Tanguay, D L Piron, L Bilodeau
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引用次数: 80

摘要

镍钛(NiTi)为冠状动脉支架的制造提供了许多优点:形状记忆、超弹性和不透光性。然而,许多作者强调,在腐蚀过程中,合金中Ni的选择性溶解可能导致潜在的毒性。通过不同的表面处理(电抛光、热处理和硝酸钝化)来提高NiTi支架的耐腐蚀性在之前的文章中有报道。在本研究中,通过体外和体内试验对这种支架进行了比较生物相容性评价。用人成纤维细胞进行细胞增殖试验,评价表面处理后NiTi的细胞毒性。然后在兔肌旁肌进行支架植入,研究相同植入物产生的炎症反应。细胞增殖试验一般表明,我们的样品的体外生物相容性类似于对照组。一项体内植入研究表明,随着时间的推移,植入物周围的纤维细胞囊厚度逐渐减少。在植入12周后,不同植入物周围的纤维囊趋向于相同的0.07 mm,这表明所有表面处理产生了相似的生物反应。纤维细胞囊的低价值表明我们的镍钛表面处理的植入物是相对惰性的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Preliminary investigation of the effects of surface treatments on biological response to shape memory NiTi stents.

Nickel-titanium (NiTi) offers many advantages for the fabrication of coronary stents: shape memory, superelasticity, and radiopacity. However, many authors highlighted the selective dissolution of Ni from the alloy during the corrosion process that could lead to potential toxicity. The improvement of the NiTi stent's corrosion resistance by different surface treatments (electropolishing, heat treatment, and nitric acid passivation) was reported in a previous article. In the present study a comparative biocompatibility evaluation of such stents was performed through in vitro and in vivo assays. A cell proliferation test was completed to evaluate the cytotoxicity of surface treated NiTi using human fibroblasts. Then a stent implantation was performed in rabbit paramuscular muscle to study the inflammatory response generated by the same implants. Cell proliferation tests generally indicated an in vitro biocompatibility of our samples similar to the control group. An in vivo implantation study demonstrated the gradual overall reduction with time of the fibrocellular capsule thickness surrounding the implants. After a 12-week implantation period, the fibrous capsules surrounding the different implants tended toward the same value of 0.07 mm, which suggested that all surface treatments produced a similar biological response. This low value of the fibrocellular capsule indicated that our NiTi surface treated implants were relatively inert.

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