Preparation of SF-gel-CS-Hap bionic biphasic porous scaffolds and evaluation of physical, mechanical and biological properties.

IF 2.3 4区医学 Q3 ENGINEERING, BIOMEDICAL

Journal of Biomaterials Applications Pub Date : 2025-03-24 DOI:10.1177/08853282251329591

Mingxi Gu, Lin Guo, Changcheng Wang, Fengde Tian, Ruihu Hao

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引用次数: 0

Abstract

Objective: Full-thickness cartilage defect are usually accompanied by subchondral bone damage, which is difficult to self-repair once damaged due to the lack of vascularization and innervation. In this study, a biphasic composite scaffold was developed by combining vacuum freeze-drying and iterative freeze-thawing with gelatin, chitosan, silk fibroin, and hydroxyapatite as the basic materials to explore the feasibility of using them for the repair of total cartilage defects. Methods and Results: Six groups of SF-CS-Gel-nHap porous scaffolds (Hap-0%, Hap-1%, Hap- 2%, Hap-3%, Hap-4%, Hap-5%) were prepared by vacuum freeze-drying and chemical cross-linking using filipin protein (SF), gelatin (Gel), chitosan (CS) and hydroxyapatite (Hap) as the base materials. A series of characterization methods were used to systematically analyze and test the morphological features as well as physical and mechanical properties of the scaffolds. Then a novel bionic biphasic porous scaffold was developed by a combination of freeze-drying and freeze-thawing using the SF-CS-Gel as the cartilage phase and the SF-CS-Gel-2%Hap as the subchondral bone phase. Finally, it was co-cultured with chondrocytes to verify the biological properties of the SF-CS-Gel/SF-CS-Gel-2%Hap bionic biphasic porous composite scaffold in vitro. The results showed that the SF-CS-Gel/SF-CS-Gel-2%Hap biphasic scaffolds had a highly porous mesh structure, with an average pore size of 156.06 ± 42.36 μm in the cartilage phase and 214.38 ± 65.82 μm in the subchondral bone phase. Co-cultured with chondrocytes, the live and dead cells stained, cck-8 growth and proliferation curves showed that the bionic scaffolds had good biocompatibility and cytotoxicity. Cytoskeletal staining showed that the morphology of chondrocytes in the bionic scaffolds could maintain three-dimensional growth as in vivo. Conclusion: The results showed that SF-CS-Gel/SF-CS-Gel-2%Hap biphasic scaffolds have good biocompatibility, biodegradability, stability, appropriate mechanical properties and porosity, and are suitable for repairing articular cartilage and subchondral bone. It is expected to be used as a repair material for articular cartilage in clinical applications.

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SF-gel-CS-Hap仿生双相多孔支架的制备及物理、力学和生物性能评价。

目的：全层软骨缺损常伴有软骨下骨损伤，由于缺乏血管化和神经支配，损伤后难以自我修复。本研究以明胶、壳聚糖、丝素蛋白、羟基磷灰石为基础材料，采用真空冷冻干燥和反复冻融相结合的方法制备双相复合支架，探讨其用于全软骨缺损修复的可行性。方法与结果：以filipin蛋白（SF）、明胶（Gel）、壳聚糖（CS）和羟基磷灰石（Hap）为基材，采用真空冷冻干燥和化学交联法制备6组SF-CS-Gel- nhap多孔支架（Hap-0%、Hap-1%、Hap- 2%、Hap-3%、Hap-4%、Hap-5%）。采用一系列表征方法，系统分析和测试了支架的形态特征和物理力学性能。以SF-CS-Gel为软骨相，SF-CS-Gel-2% hap为软骨下骨相，采用冻干和冻融相结合的方法制备了一种新型仿生双相多孔支架。最后，将其与软骨细胞共培养，体外验证SF-CS-Gel/SF-CS-Gel-2% hap仿生双相多孔复合支架的生物学特性。结果表明，SF-CS-Gel/SF-CS-Gel-2% hap双相支架具有高度多孔的网状结构，软骨期平均孔径为156.06±42.36 μm，软骨下骨期平均孔径为214.38±65.82 μm。与软骨细胞共培养，活细胞和死细胞染色，cck-8生长和增殖曲线显示仿生支架具有良好的生物相容性和细胞毒性。细胞骨架染色显示，仿生支架软骨细胞形态与体内一样能够维持三维生长。结论：SF-CS-Gel/SF-CS-Gel-2% hap双相支架具有良好的生物相容性、生物可降解性、稳定性、适当的力学性能和孔隙度，适用于关节软骨和软骨下骨的修复。它有望作为关节软骨的修复材料在临床应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomaterials Applications 工程技术-材料科学：生物材料

CiteScore

5.10

自引率

3.40%

发文量

144

审稿时长

1.5 months

期刊介绍： The Journal of Biomaterials Applications is a fully peer reviewed international journal that publishes original research and review articles that emphasize the development, manufacture and clinical applications of biomaterials. Peer-reviewed articles by biomedical specialists from around the world cover: New developments in biomaterials, R&D, properties and performance, evaluation and applications Applications in biomedical materials and devices - from sutures and wound dressings to biosensors and cardiovascular devices Current findings in biological compatibility/incompatibility of biomaterials The Journal of Biomaterials Applications publishes original articles that emphasize the development, manufacture and clinical applications of biomaterials. Biomaterials continue to be one of the most rapidly growing areas of research in plastics today and certainly one of the biggest technical challenges, since biomaterial performance is dependent on polymer compatibility with the aggressive biological environment. The Journal cuts across disciplines and focuses on medical research and topics that present the broadest view of practical applications of biomaterials in actual clinical use. The Journal of Biomaterial Applications is devoted to new and emerging biomaterials technologies, particularly focusing on the many applications which are under development at industrial biomedical and polymer research facilities, as well as the ongoing activities in academic, medical and applied clinical uses of devices.