流动化学
连续流动
生物转化
生物催化
纳米技术
生化工程
合成生物学
化学
生物炼制
聚合物
脚手架
生物相容性材料
水溶液
可生物降解聚合物
生物降解
弹性(材料科学)
材料科学
代谢活性
天然聚合物
生物膜
生物反应器
软件部署
活细胞
微生物降解
生命系统
作者
Huilin Wen,Chi‐Chang Hu,Zhaoxiang Yang,Haixia Shen,Shenming Qu,Jing Zhang,Yang Yang,Ziyi Yu
摘要
Abstract Living materials that integrate microbial consortia within synthetic scaffolds offer powerful capabilities for biocatalysis, but preserving biological activity alongside spatial structure remains a major challenge. Here, we present a strategy that embeds phase‐separated aqueous microdroplets within a 3D‐printable hydrogel matrix to create architected living materials. Aqueous two‐phase immiscibility between the droplet core and scaffold‐forming polymers ensures physical separation, maintaining discrete liquid microenvironments essential for microbial viability and metabolic cooperation. The resulting materials exhibit excellent structural fidelity, cell retention, and mechanical resilience while enabling programmable microbial organization. When implemented under continuous flow conditions, the material supports long‐term biocatalysis of a mutualistic pairing of Chlorella vulgaris and Bacillus subtilis and the degradation of azo dyes in synthetic wastewater. This strategy introduces a generalizable route for constructing compartmentalized living materials, enabling the structured deployment of microbial consortia for chemical biotransformation and process‐scale applications.
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