人工器官生物相容性杂交材料的最佳灭菌方法

IF 0.8 Q4 ENGINEERING, BIOMEDICAL
Y. Inoue, Ayaka Tashiro, Y. Kawase, T. Isoyama, I. Saito, T. Ono, Shintaro Hara, K. Ishii, Terumi Yurimoto, Y. Shiraishi, A. Yamada, T. Yambe, Y. Abe
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引用次数: 1

摘要

我们之前报道了一种新型混合医用材料的开发,该材料由具有高生物相容性的生物基材料和具有优异强度和可加工性的人工材料组成。该材料具有良好的生物相容性和良好的体内稳定性。此外,当应用于植入式传感器表面时,可以很好地控制传感器功能表面的生物反应。对于具有如此优异性能的混合材料的商业化和广泛使用,灭菌和储存是关键考虑因素,因为混合材料必须在体外加工,然后才能作为体内医疗材料应用,因此尽管尽了最大努力,仍有污染的风险。因此,本研究的目的是建立一种不影响杂交材料生物相容性的最佳灭菌方法。为此,我们测试了混合材料的六种灭菌方法:高压灭菌法(121 (cid:155) C, 20分钟),干热法(160 (cid:155) C, 120分钟),环氧乙烷气体(37 (cid:155) C, 120分钟),过氧化氢血浆(45 (cid:155) C, 45分钟)和伽马射线(25 kGy),有和没有冻干。灭菌后,与血管内皮细胞一起培养,评估植入率,并通过光镜和扫描电镜观察材料的形状和结构变化。结果表明,不冻干的伽马灭菌是该材料的最佳灭菌方法,与预先灭菌的材料相比,该材料保留了胶原网络,并且粘附的血管内皮细胞数量没有变化。这些发现有助于促进这种结合合成材料和生物基材料优点的杂化材料的商业化,在人工器官工程中广泛应用于临床。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimum Sterilization Methods of Biocompatible Hybrid Material for Artificial Organs
We previously reported the development of a new hybrid medical material comprising bio-based materials with high biocompatibility and artificial materials with characteristics of excellent strength and pro-cessability. This material shows sufficient biocompatibility and excellent stability in vivo . Moreover, when applied to the surface of an implantable sensor, the biological reaction on the sensor function surface can be well controlled. For commercialization and widespread use of hybrid materials with such superior properties, sterilization and storage are critical considerations, given that hybrid materials must be processed outside the body prior to application as medical materials in vivo , thus posing a risk of contamination despite best efforts. There-fore, the aim of the present study was to establish an optimal sterilization method that will not impair the biocompatibility of the hybrid material. Toward this end, we tested six sterilization methods for the hybrid material: autoclave (121 (cid:155) C, 20 min), dry heat (160 (cid:155) C, 120 min), ethylene oxide gas (37 (cid:155) C, 120 min), hydrogen peroxide plasma (45 (cid:155) C, 45 min), and gamma ray (25 kGy) with and without lyophilization. After sterilization, the material was cultured with vascular endothelial cells to evaluate the engraftment rate, and was observed with light and scanning electron microscopy to determine shape and structure changes. The results demonstrated that gamma sterilization without lyophilization was the best sterilization method for this material, which preserved the collagen network and showed no change in number of adhered vascular endothelial cells compared to the pre-sterilized material. These findings are useful to promote the commercialization of this hybrid material with combined advantages of synthetic and bio-based materials for widespread clinical application in the engineering of artificial organs.
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来源期刊
Advanced Biomedical Engineering
Advanced Biomedical Engineering ENGINEERING, BIOMEDICAL-
CiteScore
1.40
自引率
10.00%
发文量
15
审稿时长
15 weeks
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