Flexible keratin hydrogels obtained by a reductive method†

IF 6 2区 材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY
María Luz Peralta Ramos, Patricia Rivas-Rojas, Hugo Ascolani, Margherita Cavallo, Francesca Bonino, Roberto Fernandez de Luis, María Ximena Guerbi, Flabia Michelini, Celina Bernal, Juan Manuel Lázaro-Martínez and Guillermo Copello
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Abstract

Keratin derived materials are still underexploited due to the little understanding of their chemical versatility. Whereas many protein based materials achieve flexibility by crosslinking or interpenetrating with synthetic polymers, we assessed the effect of reductive treatments on aqueous media. Hydrazine sulphate (HZN) and ascorbic acid reduction were compared. The reduced material is bendable and stretchable, whereas the original keratin hydrogel is brittle. This would imply a technological leap in protein materials. Both reductive treatments would achieve reduced keratins by the reduction of oxidised cysteines which leads to a change in the polypeptide chain interaction by a decrease in electrostatic repulsion and swelling. Moreover, in contrast with the ascorbic acid treatment, when higher levels of HZN are employed, the effect of residual sulphates lead to the interchain closeness of the more mobile domains acting as physical crosslinkers, leading to compressed structures with narrower pores. This suggests that the flexible properties of the hydrogel could be related not only to the reduction of the hydrogel but also to the interaction of the sulphate ions with the keratin structure. As a result, the reduction of sulfinic and sulfenic groups to thiol, along with the incorporation of sulphate ions into the structure, impart the material with an elongation at break ranging between 10–25%, nano-scale pores approximately 2 nm in size, swelling capacity of around 50%, all while preserving the biocompatibility observed in the original material tested across two cell lines comprising fibroblasts and keratinocytes.

Abstract Image

通过还原法获得柔性角蛋白水凝胶†。
由于对角蛋白的化学多功能性了解甚少,因此角蛋白衍生材料仍未得到充分利用。许多基于蛋白质的材料通过与合成聚合物交联或互渗实现柔韧性,而我们则评估了还原处理对水介质的影响。我们对硫酸肼(HZN)和抗坏血酸还原进行了比较。还原后的材料可弯曲和伸展,而原来的角蛋白水凝胶则很脆。这意味着蛋白质材料技术的飞跃。这两种还原处理都是通过还原氧化半胱氨酸来实现还原角蛋白,从而通过减少静电排斥和膨胀来改变多肽链的相互作用。此外,与抗坏血酸处理不同的是,当使用较高浓度的 HZN 时,残留硫酸盐的影响会导致作为物理交联剂的较易移动结构域的链间紧密性降低,从而形成具有较窄孔隙的压缩结构。这表明,水凝胶的柔韧性不仅与水凝胶的还原有关,还与硫酸根离子与角蛋白结构的相互作用有关。因此,将亚硫酸基团和亚硫烯酸基团还原成硫醇,再将硫酸根离子加入结构中,可使材料的断裂伸长率在 10-25% 之间,纳米级孔隙大小约为 2 纳米,膨胀能力约为 50%,同时还能保持在成纤维细胞和角质细胞两种细胞系中测试的原始材料的生物相容性。
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来源期刊
Materials Chemistry Frontiers
Materials Chemistry Frontiers Materials Science-Materials Chemistry
CiteScore
12.00
自引率
2.90%
发文量
313
期刊介绍: Materials Chemistry Frontiers focuses on the synthesis and chemistry of exciting new materials, and the development of improved fabrication techniques. Characterisation and fundamental studies that are of broad appeal are also welcome. This is the ideal home for studies of a significant nature that further the development of organic, inorganic, composite and nano-materials.
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