Abstract
In recent years, a major focus in the field of tissue engineering has been the search for a suitable biomaterial for clinical applications. Researchers have sought to optimize natural, synthetic, and hybrid options, with an aim to enhance biological, chemical, physical, and mechanical properties. In the past decade, silk fibroin has emerged as a promising approach due to its suitable properties. Specifically, the chemical modification of silk fibroin with methacrylate agents, namely glycidyl methacrylate, methacrylic anhydride, and gelatin methacryloyl, confers the material with improved biophysical properties. This review presents an in-depth overview of silk fibroin's structure and suitable properties, silk fibroin methacrylate synthesis and characterization techniques, and applications of silk fibroin in bone and cartilage, skin, and nerve tissue engineering. Challenges include a limited understanding of methacrylate agents on specific cell types, which can be addressed by further in vivo investigations utilizing biomaterial compounds to confer tissue-specific needs. We conclude with our perspective of the present limitations and future trends of the methacrylated SF platform.