Constructing bio-based materials and monomer modules based on microbial fermentation

doi:10.16085/j.issn.1000-6613.2025-0090

Abstract

Abstract:

Bio-based materials are recognized as a critical enabler for advancing chemical engineering advanced materials toward industrial upgrading and transformation. This article focused on the fermentation methodologies employed in the production of bio-based materials and systematically summarized their progress across raw material, process, and product domains. The study also examined the technological barriers and challenges associated with the iterative updates of second-generation and third-generation carbon sources within the biomanufacturing industry. It proposed the construction of a multidimensional biomass carbon source supply system and guarantee mechanism. The article delved into the fermentation process technology for key polymer monomers such as ethylene glycol, 1,3-propanediol, 1,4-butanediol, succinic acid, adipic acid, and terephthalic acid, as well as polymer materials including polylactic acid, polyhydroxyalkanoates, hyaluronic acid, and bacterial cellulose. The study outlined four critical modules: bio-based plastics, bio-based rubbers, bio-based nylon, and bio-based polysaccharide materials. It advocated for enhancing the product system of bio-based materials through fermentation methods to gradually replace petrochemical-based materials, paving the way for future advancements in the field.

Key words: bio-based materials, ferment, monomers, carbon source, plastic

摘要：

生物基材料是推动化工新材料领域产业升级转型的重要支撑，本文以发酵法为核心，系统总结了生物基材料及单体模块原料端、过程端、产品端的相关进展；概括了生物制造产业背景下第二代、第三代碳源迭代更新的技术壁垒和挑战，提出构建多维生物质碳源供给体系和保障机制，以突破第一代碳源供给的局限性；围绕生物基塑料、生物基橡胶、生物基尼龙、生物基多糖材料四个模块，阐述了乙二醇、1,3-丙二醇、1,4-丁二醇、丁二酸、己二酸、对苯二甲酸等聚合物单体以及聚乳酸、聚羟基烷酸酯、透明质酸、细菌纤维素等聚合物材料的发酵工艺技术。本文还提出了完善发酵法生物基材料的产品体系，以实现石化材料的逐步替代，进而推动化工新材料领域的可持续发展。

关键词: 生物基材料, 发酵, 单体, 碳源, 塑料

CLC Number:

TQ31

WANG Liangyu, CAO Hui, TAN Tianwei. Constructing bio-based materials and monomer modules based on microbial fermentation[J]. Chemical Industry and Engineering Progress, 2025, 44(5): 2394-2406.

王良玉, 曹辉, 谭天伟. 基于微生物发酵构建生物基材料及单体模块[J]. 化工进展, 2025, 44(5): 2394-2406.

Figures/Tables 8

References 88

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单体模块	底物	菌种	滴度/g·L^-1	得率/g·g^-1	生产速率/g·L^-1·h^-1	参考文献
乙二醇	木糖	E. coli W3110	108.2	0.3600	2.250	[37]
1,3-丙二醇	甘油	K. pneumoniae LDH526	102.1	0.5200	2.130	[38]
	葡萄糖	E. coli	135.0	1.200	3.500	[38]
	葡萄糖	C. glutamicum MBP14	110.4	0.4200	2.300	[39]
1,4-丁二醇	葡萄糖	E. coli	125.0	0.4000	0.3500	[4]
对苯二甲酸	对二甲苯	E. coli DH5α	6.700	0.6200	0.2800	[44]
对苯二甲酸	对二甲苯	P. putida KT2440	38.25	0.6400	—	[45]
丁二酸	甘蔗汁	I. orientalis SD108	63.10	0.5000	0.6600	[42]
丁二酸	葡萄糖	Y. lipolytica Hi-SA2	111.9	0.7900	1.790	[5]
己二酸	葡萄糖和甘油	E. coli Mad123146	68.00	0.3800	0.8100	[70]
黏康酸	葡萄糖	C. glutamicum MA8	88.20	0.3000	—	[76]
黏康酸	木质纤维素水解液	C. glutamicum EMA1	19.90	0.3300	—	[76]
苯乙烯	葡萄糖	E. coli YHP05	5.300	—	0.09000	[34]
丁二烯	葡萄糖	E. coli CFB22	2.130	—	—	[55]

单体模块	底物	菌种	滴度/g·L^-1	得率/g·g^-1	生产速率/g·L^-1·h^-1	参考文献
乙二醇	木糖	E. coli W3110	108.2	0.3600	2.250	[37]
1,3-丙二醇	甘油	K. pneumoniae LDH526	102.1	0.5200	2.130	[38]
	葡萄糖	E. coli	135.0	1.200	3.500	[38]
	葡萄糖	C. glutamicum MBP14	110.4	0.4200	2.300	[39]
1,4-丁二醇	葡萄糖	E. coli	125.0	0.4000	0.3500	[4]
对苯二甲酸	对二甲苯	E. coli DH5α	6.700	0.6200	0.2800	[44]
对苯二甲酸	对二甲苯	P. putida KT2440	38.25	0.6400	—	[45]
丁二酸	甘蔗汁	I. orientalis SD108	63.10	0.5000	0.6600	[42]
丁二酸	葡萄糖	Y. lipolytica Hi-SA2	111.9	0.7900	1.790	[5]
己二酸	葡萄糖和甘油	E. coli Mad123146	68.00	0.3800	0.8100	[70]
黏康酸	葡萄糖	C. glutamicum MA8	88.20	0.3000	—	[76]
黏康酸	木质纤维素水解液	C. glutamicum EMA1	19.90	0.3300	—	[76]
苯乙烯	葡萄糖	E. coli YHP05	5.300	—	0.09000	[34]
丁二烯	葡萄糖	E. coli CFB22	2.130	—	—	[55]

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