Dual-Self-Crosslinking Effect of Alginate-Di-Aldehyde with Natural and Synthetic Co-Polymers as Injectable In Situ-Forming Biodegradable Hydrogel.

IF 5 3区 化学 Q1 POLYMER SCIENCE Gels Pub Date : 2024-10-11 DOI:10.3390/gels10100649
Bushra Begum, Trideva Sastri Koduru, Syeda Noor Madni, Noor Fathima Anjum, Shanmuganathan Seetharaman, Balamuralidhara Veeranna, Vishal Kumar Gupta
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Abstract

Injectable, in situ-forming hydrogels, both biocompatible and biodegradable, have garnered significant attention in tissue engineering due to their potential for creating adaptable scaffolds. The adaptability of these hydrogels, made from natural proteins and polysaccharides, opens up a world of possibilities. In this study, sodium alginate was used to synthesize alginate di-aldehyde (ADA) through periodate oxidation, resulting in a lower molecular weight and reduced viscosity, with different degrees of oxidation (54% and 70%). The dual-crosslinking mechanism produced an injectable in situ hydrogel. Initially, physical crosslinking occurred between ADA and borax via borax complexation, followed by chemical crosslinking with gelatin through a Schiff's base reaction, which takes place between the amino groups of gelatin and the aldehyde groups of ADA, without requiring an external crosslinking agent. The formation of Schiff's base was confirmed by Fourier-transform infrared (FT-IR) spectroscopy. At the same time, the aldehyde groups in ADA were characterized using FT-IR, proton nuclear magnetic resonance (¹H NMR), and gel permeation chromatography (GPC), which determined its molecular weight. Furthermore, borax complexation was validated through boron-11 nuclear magnetic resonance (¹¹B NMR). The hydrogel formulation containing 70% ADA, polyethylene glycol (PEG), and 9% gelatin exhibited a decreased gelation time at physiological temperature, attributed to the increased gelatin content and higher degree of oxidation. Rheological analysis mirrored these findings, showing a correlation with gelation time. The swelling capacity was also enhanced due to the increased oxidation degree of PEG and the system's elevated gelatin content and hydrophilicity. The hydrogel demonstrated an average pore size of 40-60 µm and a compressive strength of 376.80 kPa. The lower molecular weight and varied pH conditions influenced its degradation behavior. Notably, the hydrogel's syringeability was deemed sufficient for practical applications, further enhancing its potential in tissue engineering. Given these properties, the 70% ADA/gelatin/PEG hydrogel is a promising candidate and a potential game-changer for injectable, self-crosslinking applications in tissue engineering. Its potential to revolutionize the field is inspiring and should motivate further exploration.

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藻酸二醛与天然及合成共聚物的双重自交联效应作为可注射的原位成型生物可降解水凝胶
可注射、原位形成的水凝胶具有生物相容性和生物可降解性,由于其具有创建适应性支架的潜力,因此在组织工程领域备受关注。这些水凝胶由天然蛋白质和多糖制成,其适应性开辟了一个充满可能性的世界。在这项研究中,海藻酸钠通过高碘酸盐氧化作用合成了海藻酸二醛(ADA),从而降低了分子量和粘度,氧化程度各不相同(54% 和 70%)。双重交联机制产生了一种可注射的原位水凝胶。首先,ADA 和硼砂之间通过硼砂络合发生物理交联,然后通过希夫碱反应与明胶发生化学交联,这种反应发生在明胶的氨基和 ADA 的醛基之间,无需外加交联剂。傅立叶变换红外光谱(FT-IR)证实了希夫碱的形成。同时,利用傅立叶变换红外光谱、质子核磁共振(¹H NMR)和凝胶渗透色谱法(GPC)对 ADA 中的醛基进行了表征,并确定了其分子量。此外,还通过硼-11 核磁共振(¹¹B NMR)验证了硼砂复合物。含有 70% ADA、聚乙二醇 (PEG) 和 9% 明胶的水凝胶配方在生理温度下的凝胶时间缩短,这归因于明胶含量的增加和氧化程度的提高。流变分析也反映了这些发现,显示出与凝胶时间的相关性。由于 PEG 的氧化程度增加、体系的明胶含量和亲水性提高,溶胀能力也得到了增强。水凝胶的平均孔径为 40-60 微米,抗压强度为 376.80 千帕。较低的分子量和不同的 pH 值条件影响了其降解行为。值得注意的是,这种水凝胶的可注射性被认为足以满足实际应用的需要,从而进一步提高了其在组织工程方面的潜力。鉴于这些特性,70% ADA/明胶/PEG水凝胶是一种很有前途的候选材料,有可能改变组织工程中可注射、自交联应用的游戏规则。它给该领域带来革命性变化的潜力令人鼓舞,并将激励我们进一步探索。
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来源期刊
Gels
Gels POLYMER SCIENCE-
CiteScore
4.70
自引率
19.60%
发文量
707
审稿时长
11 weeks
期刊介绍: The journal Gels (ISSN 2310-2861) is an international, open access journal on physical (supramolecular) and chemical gel-based materials. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on the maximum length of the papers, and full experimental details must be provided so that the results can be reproduced. Short communications, full research papers and review papers are accepted formats for the preparation of the manuscripts. Gels aims to serve as a reference journal with a focus on gel materials for researchers working in both academia and industry. Therefore, papers demonstrating practical applications of these materials are particularly welcome. Occasionally, invited contributions (i.e., original research and review articles) on emerging issues and high-tech applications of gels are published as special issues.
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