阳极氧化镍钛支架支架表面内皮细胞的迁移。

Zi Wang, Naofumi Ohtsu, Kasumi Tate, Yukiko Kojima, Hanif Saifurrahman, Makoto Ohta
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引用次数: 0

摘要

背景:支架被广泛认为是治疗狭窄等心血管疾病的主要治疗方法。先前的研究表明,在支架植入过程中内皮细胞(EC)即内皮成分的损伤可导致严重的并发症,如再狭窄。为了防止再狭窄,已经对表面生物相容性进行了增强,以加速支架内皮化过程。在Ni-Ti表面进行阳极氧化处理是一种简单有效的表面改性方法,通过增强Ni-Ti支架表面的亲水性,提高其EC活性,从而提高支架表面的生物相容性。众所周知,EC的活性受血流的影响。支架结构引起的血流改变可导致EC功能障碍,从而导致再狭窄。因此,研究流动条件下Ni-Ti表面阳极氧化产生的EC活性是必要的。目的:研究内皮化过程对镍钛支架表面阳极氧化的影响。在有流动和无流动条件下,观察了阳极氧化支架支架上EC的附着和形貌。方法:设计平行板流室,产生恒壁剪应力(WSS),研究流动对EC行为的影响。通过阳极氧化制备的TiO2层增强了Ni-Ti支架支撑表面的亲水性。通过静态(无流动)和流动暴露(有流动)24 h的实验,观察氧化镍钛合金支架支撑表面EC的分布。结果:在静态条件下,阳极氧化镍钛支架支架表面EC密度高于对照组。在流动条件下,阳极氧化对支架支撑表面EC密度的增强作用减弱。在流动条件下,EC呈现出细长的纺锤形形貌。结论:与静态条件不同,在流动条件下,EC对流动的响应呈现出细长的形态。通过改善表面亲水性,阳极氧化可以促进EC向支架表面的迁移,从而加速Ni-Ti支架的内皮化过程。与静态条件相比,流动条件下的表面亲水性提高幅度较小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Migration of endothelial cells on the surface of anodized Ni-Ti stent strut.

Migration of endothelial cells on the surface of anodized Ni-Ti stent strut.

Migration of endothelial cells on the surface of anodized Ni-Ti stent strut.

Migration of endothelial cells on the surface of anodized Ni-Ti stent strut.

Background: Stent is widely regarded as the main treatment for curing cardiovascular diseases such as stenosis. Previous research has revealed that the damage of endothelial cells (EC), i.e., the components of endothelium, during stent implantation, could lead to severe complications, such as restenosis. To prevent restenosis, enhancements have been made to surface biocompatibility to accelerate the stent endothelialization process. Anodization on the Ni-Ti is a simple and efficient surface modification method to improve the biocompatibility of the Ni-Ti stent surfaces by enhancing the surface hydrophilicity, leading to an increase in the EC activities. The EC activity is known to be affected by the blood flow. Flow change by stent structure may result in EC dysfunctions, thereby leading to restenosis. It is thus essential to investigate the EC activities resulting from the anodization on the Ni-Ti surface under flow conditions.

Objective: To study the influence of the endothelialization process on the Ni-Ti stent surface through anodization. The EC attachment and morphology on the anodized stent strut were observed under both with and without the flow conditions.

Method: A parallel plate flow chamber was designed to generate a constant wall shear stress (WSS) to study the flow effect on the EC behavior. The hydrophilicity of the Ni-Ti stent strut surface was enhanced by a TiO2 layer fabricated via anodization. The EC distribution on the surface of the anodized nitinol stent strut was observed after 24 h of static (without flow) and flow exposure (with flow) experiment.

Results: Under the static condition, the EC density on the surface of the anodized Ni-Ti stent strut was higher compared with the control. Under the flow condition, the enhancement of the EC density on the surface of the stent strut with anodization was reduced. The EC demonstrates a long and thin spindle-shaped morphology under the flow condition.

Conclusion: Unlike the static condition, the EC is demonstrating a long and thin morphology in response to the flow under the flow condition. By improving the surface hydrophilicity, the anodization could enhance the EC migration onto the strut surface, and subsequently, accelerate the Ni-Ti stent endothelialization process. The improvement of the surface hydrophilicity is lower under the flow conditions when compared with the static conditions.

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