Embedded 3D printing has revolutionized the creation of soft and intricate biological structures. By extruding a liquid filament into a supportive matrix with specific yield stress properties, this technique enables the production of delicate features beyond the capabilities of traditional 3D printing. For those unfamiliar with this method, imagine it like drawing with syrup into a bowl of thick yogurt, where the syrup remains in precise patterns without spreading. The image displayed shows a soft fiber structure, illuminated under ultraviolet light and approximately 100 microns in size, demonstrating this technology's ability to craft biocompatible structures with exceptional precision and stability. The matrix, an aqueous microgel suspension, supports the uncured filament during printing, which polymerizes to achieve the desired structure. My research harnesses this technology to replicate complex biological structures such as spider webs and hagfish slime threads, thereby enhancing the design of biomimetic materials for a range of applications and simultaneously addressing technological limitations to refine precision.