Enric Casanova-Batlle, Maria Ros, Emma Polonio-Alcalá, Sira Ausellé-Bosch, Teresa Puig, A. Guerra, Joaquim Ciurana
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Initial tests revealed that overnight incubation of fetal bovine serum significantly increased cell viability in hydrogels. Viability assays confirmed that SF substantially improved cell viability compared to PVA alone. The method was extended to fabricate SF-coated stents, which demonstrated robust cell proliferation and improved performance compared to electrospun polycaprolactone scaffolds. In addition, the SF-coated stents displayed an increase in compressive strength, demonstrating improved biocompatibility and mechanical performance. Dynamic mechanical analysis evaluated the positive impact of SF on stent properties at physiological temperatures. The study revealed that PVA-SF stents offer a compromise between biocompatibility, mechanical strength, and elastic recovery, positioning them as a valuable alternative for cardiovascular stent applications. 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引用次数: 0
摘要
生物可吸收支架(BRS)是使用生物可降解材料制造的。作为商用支架常用材料的替代品,本研究探讨了使用聚乙烯醇(PVA)和丝纤维素(SF)开发生物可吸收支架的问题。聚乙烯醇具有生物相容性和机械属性,与主动脉血管的机械属性非常相似,因此是一种很有希望用于制造 BRS 的材料。然而,其应用在细胞粘附和增殖方面存在挑战。SF 因其增强细胞粘附和增殖的潜力而被广泛研究,使其成为医疗器械领域一种前景广阔的生物材料。通过在 PVA 溶液中溶解 SF 或在水凝胶表面涂上一层 SF,引入了 SF。初步测试表明,胎牛血清过夜培养可显著提高水凝胶中的细胞活力。活力测定证实,与单独使用 PVA 相比,SF 大大提高了细胞活力。该方法被扩展用于制造 SF 涂层支架,与电纺聚己内酯支架相比,SF 涂层支架具有更强的细胞增殖能力和更好的性能。此外,SF 涂层支架的抗压强度也有所提高,这表明生物相容性和机械性能得到了改善。动态力学分析评估了 SF 在生理温度下对支架性能的积极影响。研究结果表明,PVA-SF 支架在生物相容性、机械强度和弹性恢复之间实现了折中,可作为心血管支架应用的重要替代品。增强生物相容性和改善机械性能的双重优势使 SF 涂层支架有望成为生物可吸收支架设计的候选材料。
Polyvinyl alcohol-silk fibroin composite stents: A comprehensive investigation into biocompatibility and mechanical performance
Bioresorbable stents (BRS) are manufactured using biodegradable materials. As an alternative to those commonly used in commercial stents, this study explored the development of BRS using polyvinyl alcohol (PVA) and silk fibroin (SF). PVA is a promising material for the fabrication of BRS due to its biocompatibility and mechanical attributes, closely resembling those of aortic vessels. However, its application presents challenges in terms of cell adhesion and proliferation. SF has been extensively studied for its potential to enhance cell adhesion and proliferation, making it a promising biomaterial in the field of medical devices. SF was introduced by dissolving it in a PVA solution or by coating the hydrogel surface with a layer of SF. Initial tests revealed that overnight incubation of fetal bovine serum significantly increased cell viability in hydrogels. Viability assays confirmed that SF substantially improved cell viability compared to PVA alone. The method was extended to fabricate SF-coated stents, which demonstrated robust cell proliferation and improved performance compared to electrospun polycaprolactone scaffolds. In addition, the SF-coated stents displayed an increase in compressive strength, demonstrating improved biocompatibility and mechanical performance. Dynamic mechanical analysis evaluated the positive impact of SF on stent properties at physiological temperatures. The study revealed that PVA-SF stents offer a compromise between biocompatibility, mechanical strength, and elastic recovery, positioning them as a valuable alternative for cardiovascular stent applications. The dual benefits of enhanced biocompatibility and improved mechanical performance make SF-coated stents promising candidates for bioresorbable stent design.
期刊介绍:
The International Journal of Bioprinting is a globally recognized publication that focuses on the advancements, scientific discoveries, and practical implementations of Bioprinting. Bioprinting, in simple terms, involves the utilization of 3D printing technology and materials that contain living cells or biological components to fabricate tissues or other biotechnological products. Our journal encompasses interdisciplinary research that spans across technology, science, and clinical applications within the expansive realm of Bioprinting.