Abstract
The outstanding combination of high tensile strength and extensibility of spider silk is believed to contribute to the material’s toughness. Thus, there is great interest in engineering silk for biomedical products such as suture or implants. Additionally, over the years, many studies have also sought to enhance the mechanical properties of spider silk for wider applicability, e.g., by irradiating the material using ultra-violet radiation. However, the limitations surrounding the use of ultra-violet radiation for enhancing the mechanical properties of spider silk are not well-understood. Here, we have analyzed the mechanical properties of spider silk at short ultra-violet irradiation duration. Specimens of spider silk were subjected to ultra-violet irradiation (254-nm wavelength, i.e. UVC) for 10, 20, and 30 min, respectively, followed by tensile test to rupture to determine the strength (maximum stress), extensibility (rupture strain), and toughness (strain energy density to rupture). Controls, i.e., specimens that did not received UVC, were also subjected to tensile test to rupture to determine the respective mechanical properties. One-way analysis of variance reveals that these properties decrease significantly (p < 0.05) with increasing irradiation duration. Among the three mechanical parameters, the strength of the spider silk degrades most rapidly; the extensibility of the spider silk degrades the slowest. Overall, these changes correspond to the observed surface modifications as well as the bond rupture between the peptide chains of the treated silk. Altogether, this simple but comprehensive study provides some key insights into the dependence of the mechanical properties on ultra-violet irradiation duration.
Highlights
The current challenge in material engineering is the production of light-weight materials with high strength, extensibility, and toughness
This study has investigated the mechanical properties, morphological changes, and biochemical composition of spider silk exposed to UVC radiation for short irradiation durations
The conclusions are as follows: 1. The spider silk experiences decrease in fracture strength, extensibility, and fracture toughness with increased irradiation duration
Summary
The current challenge in material engineering is the production of light-weight materials with high strength, extensibility, and toughness. Spider silk has far-reaching biomedical applications [5,6]; it can be processed into films and scaffolds to improve tissue regeneration in skin, nerve, bone, and cartilage [6,7,8] or to repair ruptured connective tissues such as tendons and ligaments [5,9,10]. These films and scaffolds can provide structural support for the cells when the cells are seeded onto them [7]. Since the recombinant spider silk proteins have the ability to repair damaged nerves and tissues, it makes sense to explore novel wound dressings made from spider silk protein [10]
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