Rafael O. Moreno-Tortolero, Juliusz Michalski, Eleanor Wells, Flora Gibb, Nick Skaer, Robert Walker, Louise Serpell, Chris Holland, Sean A. Davis
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引用次数: 0
摘要
丝绸的卓越性能源于它的分层结构,这种结构是在低能条件下由pH值和流动应力驱动的水溶液到固体纤维的自然转化过程中形成的。相比之下,人造丝的制造通常依赖于基于挤压的方法,使用凝固浴和非天然溶剂,限制了真正的仿生复制。在这里,我们发现天然丝素蛋白在空气-水界面形成粘弹性膜。利用这一点,我们展示了一种温和的全水方法,可以无缝地拉出具有共排列纳米纤维束的丝状纤维。纤维结构从低拉速下的六边形填充β-螺线管单元过渡到高拉速下的富β片结构。接近生理速度(26.3 mm s-¹)的纤维表现出最佳的力学性能,弹性模量为8±1 GPa,韧性为8±5 MJ m-³,与天然丝相当。该平台还可以嵌入纳米颗粒和生物制剂,在传感器、生物催化和组织工程中提供广泛的应用,扩大了丝绸基复合材料的潜力。人造丝的制造依赖于基于挤压的方法,缺乏真正的仿生复制。在这里,由共排列的纳米纤维束组成的丝状纤维是从空气-水界面产生的薄膜中拉出来的
Manipulating the water–air interface to drive protein assembly for functional silk-like fibroin fibre production
Silk’s remarkable properties arise from its hierarchical structure, formed through natural transformation from an aqueous solution to a solid fibre driven by pH and flow stress under low-energy conditions. In contrast, artificial silk fabrication typically relies on extrusion-based methods using coagulating baths and unnatural solvents, limiting true biomimetic replication. Here, we find that native-like silk fibroin forms viscoelastic films at the air-water interface. Utilizing this, we demonstrate a mild, all-aqueous method to seamlessly pull silk-like fibres with co-aligned nanofibrillar bundles. The fiber structure transitioned from hexagonally packed β-solenoid units at low pulling speeds to β-sheet-rich structures at higher speeds. Fibers pulled near physiological speeds (26.3 mm s-¹) exhibited optimal mechanical properties, with an elastic modulus of 8 ± 1 GPa and toughness of 8 ± 5 MJ m-³, comparable to natural silk. This platform also enables embedding nanoparticles and biologics, offering broad applications in sensors, biocatalysis, and tissue engineering, expanding the potential of silk-based composite materials. Artificial silk fabrication relies on extrusion-based methods that lack true biomimetic replication. Here, silk-like fibres composed of co-aligned nanofibrillar bundles are pulled from films produced at the air-water interface
期刊介绍:
Communications Materials, a selective open access journal within Nature Portfolio, is dedicated to publishing top-tier research, reviews, and commentary across all facets of materials science. The journal showcases significant advancements in specialized research areas, encompassing both fundamental and applied studies. Serving as an open access option for materials sciences, Communications Materials applies less stringent criteria for impact and significance compared to Nature-branded journals, including Nature Communications.
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