In situ biosynthesis of bacterial cellulose hydrogel spheroids with tunable dimensions
Bianjing Sun, Ping Wang, Jingang Zhang, Jian‐Bin Lin, Lingling Sun, Xiaokun Wang, Chuntao Chen, Dongping Sun
Abstract
Bacterial cellulose (BC) hydrogel spheroid plays a significant role in diverse fields due to its spatial 3D structure and properties. In the present work, a series of BC spheroids with controllable size and shape was obtained via an in situ biosynthesis. Crucial factors for fabricating BC spheroid including inoculum concentration of 1.35 × 103 CFU/mL, shaking speeds at 100 r/min, and 48–96 h incubation time during the biosynthetic process, were comprehensively established. An operable mechanism model for tuning the size of BC spheroids from 0.4 to 5.0 mm was proposed with a fresh feeding medium strategy of dynamic culture. The resulting BC spheroids exhibit an interactive 3D network of nanofibers, a crystallinity index of 72.3%, a specific surface area of 91.2 m2/g, and good cytocompatibility. This study reinforces the understanding of BC spheroid formation and explores new horizons for the design of BC spheroids-derived functional matrix materials for medical care.