Microstructure of the silk fibroin-based hydrogel scaffolds derived from the orb-web spider Trichonephila clavata

• Published in: Applied microscopy Vol. 54; no. 1; p. 3
• Main Authors: Sun, Yan, Ku, Bon-Jin, Moon, Myung-Jin
• Format: Journal Article
• Language: English
• Published: Singapore Springer Nature Singapore 10.02.2024; Springer Nature B.V; SpringerOpen
• Subjects: Biomedical materials; Chemistry and Materials Science; Crosslinking; Elongated structure; Fibers; Hydrogel; Hydrogels; Insects; Materials Science; Mechanical properties; Microstructure; Porosity; Regenerative medicine; Scaffold; Scaffolds; Silk; Silk fibroin; Silk gland; Silkworms; Spider; Spiders; Substrates; Tissue engineering; Webs; Spider; Silk; Hydrogel; Scaffold; Microstructure
• ISSN: 2287-4445; 2287-5123; 2287-4445
• DOI: 10.1186/s42649-024-00096-x

Due to the unique properties of the silk fibroin (SF) made from silkworm, SF-based hydrogels have recently received significant attention for various biomedical applications. However, research on the SF-based hydrogels isolated from spider silks has been rtricted due to the limited collection and preparation of naïve silk materials. Therefore, this study focused on the microstructural characteristics of hydrogel scaffolds derived from two types of woven silk glands: the major ampullate gland (MAG) and the tubuliform gland (TG), in the orb-web spider Trichonephila clavate . We compared these spider glands with those of the silk fibroin (SF) hydrogel scaffold extracted from the cocoon of the insect silkworm Bombyx mori . Our FESEM analysis revealed that the SF hydrogel has high porosity, translucency, and a loose upper structure, with attached SF fibers providing stability. The MAG hydrogel displayed even higher porosity, as well as elongated fibrous structures, and improved mechanical properties: while the TG hydrogel showed increased porosity, ridge-like or wall-like structures, and stable biocapacity formed by physical crosslinking. Due to their powerful and versatile microstructural characteristics, the MAG and TG hydrogels can become tailored substrates, very effective for tissue engineering and regenerative medicine applications.