Bacterial Cellulose for Scalable and Sustainable Bio-Gels in the Circular Economy DOI Creative Commons
Giovanni Venturelli, Federica Villa, Mariagioia Petraretti

и другие.

Gels, Год журнала: 2025, Номер 11(4), С. 262 - 262

Опубликована: Апрель 2, 2025

Microbial-derived materials are emerging for applications in biomedicine, sensors, food, cosmetics, construction, and fashion. They offer considerable structural properties process reproducibility compared to other bio-based materials. However, challenges related efficient sustainable large-scale production of microbial-derived must be addressed exploit their potential fully. This review analyzes the synergistic contribution circular, sustainable, biotechnological approaches enhance bacterial cellulose (BC) fine-tune its physico-chemical properties. BC was chosen as an ideal example due mechanical strength chemical stability, making it promising industrial applications. The discusses upcycling strategies that utilize waste microbial fermentation, simultaneously boosting production. Additionally, biotechnology techniques identified key yield tailor Among different areas where cellulose-based employed, shows promise mitigating environmental impact garment industry. emphasizes integrating circular could significantly improve tunability these may provide benefits, depending on future progresses. Future advancements should prioritize fermentation expand

Язык: Английский

Bacterial Cellulose for Scalable and Sustainable Bio-Gels in the Circular Economy DOI Creative Commons
Giovanni Venturelli, Federica Villa, Mariagioia Petraretti

и другие.

Gels, Год журнала: 2025, Номер 11(4), С. 262 - 262

Опубликована: Апрель 2, 2025

Microbial-derived materials are emerging for applications in biomedicine, sensors, food, cosmetics, construction, and fashion. They offer considerable structural properties process reproducibility compared to other bio-based materials. However, challenges related efficient sustainable large-scale production of microbial-derived must be addressed exploit their potential fully. This review analyzes the synergistic contribution circular, sustainable, biotechnological approaches enhance bacterial cellulose (BC) fine-tune its physico-chemical properties. BC was chosen as an ideal example due mechanical strength chemical stability, making it promising industrial applications. The discusses upcycling strategies that utilize waste microbial fermentation, simultaneously boosting production. Additionally, biotechnology techniques identified key yield tailor Among different areas where cellulose-based employed, shows promise mitigating environmental impact garment industry. emphasizes integrating circular could significantly improve tunability these may provide benefits, depending on future progresses. Future advancements should prioritize fermentation expand

Язык: Английский

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