Article(id=1148993957645836657, tenantId=1146029695717560320, journalId=1146031712061968385, issueId=1148993956857307504, articleNumber=null, orderNo=null, doi=10.12211/2096-8280.2024-011, pmid=null, cstr=null, oa=null, hot=null, price=null, onlineType=0, articleFormat=0, articleType=null, articleTypeStr=null, receivedDate=1705939200000, receivedDateStr=2024-01-23, revisedDate=1713888000000, revisedDateStr=2024-04-24, acceptedDate=null, acceptedDateStr=null, onlineDate=1751871106777, onlineDateStr=2025-07-07, pubDate=1735574400000, pubDateStr=2024-12-31, doiRegisterDate=null, doiRegisterDateStr=null, onlineIssueDate=1751871106777, onlineIssueDateStr=2025-07-07, onlineJustAcceptDate=null, onlineJustAcceptDateStr=null, onlineFirstDate=null, onlineFirstDateStr=null, sourceXml=null, magXml=null, createTime=1751871106777, creator=13701087609, updateTime=1751871106777, updator=13701087609, issue=Issue{id=1148993956857307504, tenantId=1146029695717560320, journalId=1146031712061968385, year='2024', volume='5', issue='6', pageStart='1227', pageEnd='1529', issueExtLink='null', onlineDate='null', pubDate='null', beforeIssueId=null, nextIssueId=null, price=null, status=1, issueComplete=1, articleOrder=1, issueType=-1, specialIssue=null, createTime=1751871106590, creator=13701087609, updateTime=1752057237502, updator=13701087609, preIssue=null, nextIssue=null, ext={EN=IssueExt(id=1149774646557499609, tenantId=1146029695717560320, journalId=1146031712061968385, issueId=1148993956857307504, language=EN, specialIssueTitle=, coverIllustrator=null, specialIssueEditor=, specialIssueAbout=), CN=IssueExt(id=1149774646557499610, tenantId=1146029695717560320, journalId=1146031712061968385, issueId=1148993956857307504, language=CN, specialIssueTitle=, coverIllustrator=null, specialIssueEditor=, specialIssueAbout=)}, issueFiles=null}, startPage=1242, endPage=1263, ext={EN=ArticleExt(id=1149994723025499030, articleId=1148993957645836657, tenantId=1146029695717560320, journalId=1146031712061968385, language=EN, title=Synthesis of organic acids from lignocellulose by biotransformation, columnId=1149894683619635652, journalTitle=Synthetic Biology Journal, columnName=Invited Review, runingTitle=null, highlight=null, articleAbstract=
The development of environmentally benign, biodegradable materials is considered an important way to address “white pollution”. Importantly, organic acid is one of the crucial monomers for preparing biodegradable materials. In recent years, the synthesis of organic acids through green and efficient methods has attracted much attention. As the most promising carbon source recognized for renewability and affordability, lignocellulose is considered a promising carbon source for the biochemical industry. Converting lignocellulose into organic acid is critical to preparing biodegradable materials and achieving carbon neutrality, which meets the requirements of the green and sustainable development strategy. Hence, researchers are focusing their investigations on the lignocellulose biorefinery. To date, innovations in synthetic biology have significantly advanced organic acid manufacturing. For example, the yield of succinic acid has exceeded 150 g/L, which facilitates the formation and development of the bio-based biodegradable materials industry. In this paper, various lignocellulose pretreatment technologies were reviewed, including physical, chemical, biological, physicochemical, and other emerging pretreatment methods. To realize the goal of efficient utilization of lignocellulose, the refining processes of lignocellulose were also reviewed, including detoxification of inhibitors, reductive catalytic fractionation, consolidated bioprocessing, and other methods. After the pretreatment and refining process, lignocellulose is transformed to sugars and aromatic compounds, which can be utilized for producing various organic acid compounds, such as succinic acid, 3-hydroxypropionic acid, cis,cis-muconic acid, 2,5-furandicarboxylic acid, 2-pyrone-4,6-dicarboxylic acid. Next, using the optimization of production of these organic acid compounds as examples, several synthetic biology strategies were summarized, including constructing biosynthetic pathways, optimizing regulatory elements, enlarging the substrates spectrum, and other strategies for improving cell production capacity. Finally, the development trends of the biodegradable materials industry are summarized and prospected. The development of emerging pretreatment and consolidated bioprocessing to facilitate the efficiency of lignocellulose utilization were discussed. Improving the robustness of microbial cell factories and designing the systematic lignocellulose conversion pathways could further optimize the performances of organic acid synthesis. The insights given in this review could facilitate further development on the industrial production of biodegradable materials, towards addressing the global energy crisis and “white pollution”. ![]()
, correspAuthors=null, authorNote=null, correspAuthorsNote=null, copyrightStatement=null, copyrightOwner=null, extLink=null, articleAbsUrl=null, sourceXml=null, magXml=null, pdfUrl=null, pdf=null, pdfFileSize=null, pdfExtLink=null, richHtmlUrl=null, mobilePdfUrl=null, reviewReport=null, pdfFirstPage=null, abstractGraph=null, abstractGraphContent=null, abstractVideo=null, citation=null, cebUrl=null, magXmlContent=null, mapNumber=null, authorCompany=null, fund=null, authors=null, authorsList=Meng CHAI, Fengqing WANG, Dongzhi WEI), CN=ArticleExt(id=1148993962800636391, articleId=1148993957645836657, tenantId=1146029695717560320, journalId=1146031712061968385, language=CN, title=综合利用木质纤维素生物转化合成有机酸, columnId=1148682685129748680, journalTitle=合成生物学, columnName=特约评述, runingTitle=null, highlight=null, articleAbstract=
开发环境友好型的生物可降解材料,被公认为是解决“白色污染”的重要途径。作为制备生物可降解材料的主要原料之一,有机酸的绿色高效制造备受关注。木质纤维素是储量庞大且可再生的自然资源,以木质纤维素为原料,通过生物转化的方式生产有机酸,是发展绿色可降解生物基材料的理想途径,具有过程绿色低碳的优势,符合绿色可持续发展经济的需求。近年来,人们针对木质纤维素的生物炼制开展了大量研究,并在生物转化合成有机酸等领域取得了重要进展,特别是在高产有机酸微生物细胞工厂的设计开发上不断取得突破,使得生物基有机酸的生产水平屡创新高,丁二酸等品种的产量甚至突破了150 g/L,积极推动了生物基可降解材料产业的形成和发展。本文介绍了木质纤维素的组分并总结了木质纤维素的物理预处理法、化学预处理法、生物预处理法、物理-化学共处理法和化学-生物共处理法等多种预处理技术,以及抑制物的脱毒技术、还原催化分馏工艺、催化剂的回收、偶联木质纤维素水解和发酵的制造工艺。并以木质纤维素为原料合成的高价值有机酸(丁二酸、3-羟基丙酸、黏康酸、2,5-呋喃二甲酸和2-吡喃酮-4,6-二羧酸)为例,从这些有机酸的生物合成途径,合成生物学改造策略和发酵条件优化等角度探讨了这些有机酸的研究现状。最后,对当前生物可降解材料产业链的发展趋势进行了总结和展望,讨论了开发新型预处理技术和优化联合生物处理工艺等策略对木质纤维素组分解离和利用的重要意义,并从提高微生物细胞工厂的鲁棒性以及设计木质纤维素的综合转化途径等方面进行系统分析,以期能为有机酸的工业化生产提供参考。
, correspAuthors=null, authorNote=null, correspAuthorsNote=null, copyrightStatement=null, copyrightOwner=null, extLink=null, articleAbsUrl=null, sourceXml=GI0Ss8E141HdrqFxamk9+g==, magXml=1XJN/Ww7bWg2dLiz6nDFZw==, pdfUrl=null, pdf=8ATYus2Sqh3t/bB+gO0/tA==, pdfFileSize=null, pdfExtLink=null, richHtmlUrl=null, mobilePdfUrl=null, reviewReport=null, pdfFirstPage=null, abstractGraph=null, abstractGraphContent=null, abstractVideo=null, citation=null, cebUrl=null, magXmlContent=k2FnRL3OclNwEmdajF5a1w==, mapNumber=null, authorCompany=null, fund=null, authors=
 |
王风清 (1977—) , 男, 教授, 博士生导师。研究方向为利用代谢工程和合成生物学的原理和方法, 致力于微生物细胞工厂的研究和开发等。E-mail:fqwang@ecust.edu.cn |
 |
魏东芝(1963—),男,教授,博士生导师。研究方向为生物元器件的发现、改造与应用研究,致力于发现和改进具有工业应用价值的微生物和生物催化剂,开拓生物转化新反应等。E-mail:dzhwei@ecust.edu.cn |
, authorsList=柴猛, 王风清, 魏东芝)}, authors=[Author(id=1164877075027599830, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, orderNo=0, firstName=null, middleName=null, lastName=null, nameCn=null, orcid=null, stid=null, country=null, authorPic=null, dead=0, email=chaimeng980909@163.com, emailSecond=null, emailThird=null, correspondingAuthor=0, authorType=1, ext={EN=AuthorExt(id=1164877075161817561, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075027599830, language=EN, stringName=Meng CHAI, firstName=Meng, middleName=null, lastName=CHAI, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, address=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China
2 Luhua Institute of Biotechnology,Shanghai 200237,China, bio=null, bioImg=null, bioContent=null, aboutCorrespAuthor=null), CN=AuthorExt(id=1164877075228926426, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075027599830, language=CN, stringName=柴猛, firstName=null, middleName=null, lastName=null, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, address=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237
2 鲁华生物技术研究所,上海 200237, bio={"img":"LC4IOaaxHvL9Q76oMEimqA==","content":"
柴猛(1998—),男,博士研究生。研究方向为合成生物学与代谢工程。E-mail:chaimeng980909@163.com
"}, bioImg=LC4IOaaxHvL9Q76oMEimqA==, bioContent=
柴猛(1998—),男,博士研究生。研究方向为合成生物学与代谢工程。E-mail:chaimeng980909@163.com
, aboutCorrespAuthor=null)}, companyList=[AuthorCompany(id=1164877074754970060, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=1, ext=[AuthorCompanyExt(id=1164877074763358669, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074771747278, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237)]), AuthorCompany(id=1164877074851439055, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=2, ext=[AuthorCompanyExt(id=1164877074859827664, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 Luhua Institute of Biotechnology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074864021969, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 鲁华生物技术研究所,上海 200237)])]), Author(id=1164877075304423900, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, orderNo=1, firstName=null, middleName=null, lastName=null, nameCn=null, orcid=null, stid=null, country=null, authorPic=null, dead=0, email=fqwang@ecust.edu.cn, emailSecond=null, emailThird=null, correspondingAuthor=0, authorType=1, ext={EN=AuthorExt(id=1164877075379921376, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075304423900, language=EN, stringName=Fengqing WANG, firstName=Fengqing, middleName=null, lastName=WANG, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, 3, address=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China
2 Luhua Institute of Biotechnology,Shanghai 200237,China
3 Key Laboratory of Biocatalysis and Intelligent Manufacturing of China Light Industry,Shanghai 200237,China, bio=null, bioImg=null, bioContent=null, aboutCorrespAuthor=null), CN=AuthorExt(id=1164877075442835937, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075304423900, language=CN, stringName=王风清, firstName=null, middleName=null, lastName=null, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, 3, address=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237
2 鲁华生物技术研究所,上海 200237
3 中国轻工业生物催化与智能制造重点实验室,上海 200237, bio={"img":"aE99p+VBAC+2DhkPmFSeNg==","content":"
王风清 (1977—) , 男, 教授, 博士生导师。研究方向为利用代谢工程和合成生物学的原理和方法, 致力于微生物细胞工厂的研究和开发等。E-mail:fqwang@ecust.edu.cn
"}, bioImg=aE99p+VBAC+2DhkPmFSeNg==, bioContent=
王风清 (1977—) , 男, 教授, 博士生导师。研究方向为利用代谢工程和合成生物学的原理和方法, 致力于微生物细胞工厂的研究和开发等。E-mail:fqwang@ecust.edu.cn
, aboutCorrespAuthor=null)}, companyList=[AuthorCompany(id=1164877074754970060, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=1, ext=[AuthorCompanyExt(id=1164877074763358669, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074771747278, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237)]), AuthorCompany(id=1164877074851439055, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=2, ext=[AuthorCompanyExt(id=1164877074859827664, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 Luhua Institute of Biotechnology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074864021969, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 鲁华生物技术研究所,上海 200237)]), AuthorCompany(id=1164877074931130834, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=3, ext=[AuthorCompanyExt(id=1164877074939519443, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 Key Laboratory of Biocatalysis and Intelligent Manufacturing of China Light Industry,Shanghai 200237,China), AuthorCompanyExt(id=1164877074947908052, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 中国轻工业生物催化与智能制造重点实验室,上海 200237)])]), Author(id=1164877075505750499, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, orderNo=2, firstName=null, middleName=null, lastName=null, nameCn=null, orcid=null, stid=null, country=null, authorPic=null, dead=0, email=dzhwei@ecust.edu.cn, emailSecond=null, emailThird=null, correspondingAuthor=0, authorType=1, ext={EN=AuthorExt(id=1164877075589636583, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075505750499, language=EN, stringName=Dongzhi WEI, firstName=Dongzhi, middleName=null, lastName=WEI, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, 3, address=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China
2 Luhua Institute of Biotechnology,Shanghai 200237,China
3 Key Laboratory of Biocatalysis and Intelligent Manufacturing of China Light Industry,Shanghai 200237,China, bio=null, bioImg=null, bioContent=null, aboutCorrespAuthor=null), CN=AuthorExt(id=1164877075648356840, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, authorId=1164877075505750499, language=CN, stringName=魏东芝, firstName=null, middleName=null, lastName=null, prefix=null, suffix=null, authorComment=null, nameInitials=null, affiliation=null, department=null, xref=
1, 2, 3, address=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237
2 鲁华生物技术研究所,上海 200237
3 中国轻工业生物催化与智能制造重点实验室,上海 200237, bio={"img":"kJCaOKq8qIGM8nO04KumFw==","content":"
魏东芝(1963—),男,教授,博士生导师。研究方向为生物元器件的发现、改造与应用研究,致力于发现和改进具有工业应用价值的微生物和生物催化剂,开拓生物转化新反应等。E-mail:dzhwei@ecust.edu.cn
"}, bioImg=kJCaOKq8qIGM8nO04KumFw==, bioContent=
魏东芝(1963—),男,教授,博士生导师。研究方向为生物元器件的发现、改造与应用研究,致力于发现和改进具有工业应用价值的微生物和生物催化剂,开拓生物转化新反应等。E-mail:dzhwei@ecust.edu.cn
, aboutCorrespAuthor=null)}, companyList=[AuthorCompany(id=1164877074754970060, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=1, ext=[AuthorCompanyExt(id=1164877074763358669, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074771747278, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237)]), AuthorCompany(id=1164877074851439055, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=2, ext=[AuthorCompanyExt(id=1164877074859827664, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 Luhua Institute of Biotechnology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074864021969, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 鲁华生物技术研究所,上海 200237)]), AuthorCompany(id=1164877074931130834, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=3, ext=[AuthorCompanyExt(id=1164877074939519443, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 Key Laboratory of Biocatalysis and Intelligent Manufacturing of China Light Industry,Shanghai 200237,China), AuthorCompanyExt(id=1164877074947908052, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 中国轻工业生物催化与智能制造重点实验室,上海 200237)])])], keywords=[Keyword(id=1164877075753214441, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, orderNo=1, keyword=lignocellulose), Keyword(id=1164877075807740394, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, orderNo=2, keyword=organic acids), Keyword(id=1164877075879043563, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, orderNo=3, keyword=bio-based materials), Keyword(id=1164877075941958124, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, orderNo=4, keyword=green biomanufacturing), Keyword(id=1164877076009066989, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, orderNo=5, keyword=synthetic biology), Keyword(id=1164877076063592942, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, orderNo=1, keyword=木质纤维素), Keyword(id=1164877076122313199, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, orderNo=2, keyword=有机酸), Keyword(id=1164877076181033456, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, orderNo=3, keyword=生物基材料), Keyword(id=1164877076239753713, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, orderNo=4, keyword=绿色生物制造), Keyword(id=1164877076315251186, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, orderNo=5, keyword=合成生物学)], refs=[Reference(id=1164877077896503816, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=317, issue=null, pageStart=120747, pageEnd=null, url=null, language=null, rfNumber=1, rfOrder=0, authorNames=SEWWANDI M, WIJESEKARA H, RAJAPAKSHA A U, journalName=Environmental Pollution, refType=null, unstructuredReference=
SEWWANDI M,
WIJESEKARA H,
RAJAPAKSHA A U, et al. Microplastics and plastics-associated contaminants in food and beverages; global trends, concentrations, and human exposure[J].
Environmental Pollution,
2023,
317: 120747., articleTitle=Microplastics and plastics-associated contaminants in food and beverages; global trends, concentrations, and human exposure, refAbstract=null), Reference(id=1164877077967806985, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=347, issue=null, pageStart=126697, pageEnd=null, url=null, language=null, rfNumber=2, rfOrder=1, authorNames=SINGH JADAUN J, BANSAL S, SONTHALIA A, journalName=Bioresource Technology, refType=null, unstructuredReference=
SINGH JADAUN J,
BANSAL S,
SONTHALIA A, et al. Biodegradation of plastics for sustainable environment[J].
Bioresource Technology,
2022,
347: 126697., articleTitle=Biodegradation of plastics for sustainable environment, refAbstract=null), Reference(id=1164877078026527242, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=1, issue=2, pageStart=188, pageEnd=206, url=null, language=null, rfNumber=3, rfOrder=2, authorNames=WANG S Y, CHENG A H, LIU F H, journalName=Industrial Chemistry & Materials, refType=null, unstructuredReference=
WANG S Y,
CHENG A H,
LIU F H, et al. Catalytic conversion network for lignocellulosic biomass valorization: a panoramic view[J].
Industrial Chemistry & Materials,
2023,
1(2): 188-206., articleTitle=Catalytic conversion network for lignocellulosic biomass valorization: a panoramic view, refAbstract=null), Reference(id=1164877078093636107, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=15, issue=4, pageStart=829, pageEnd=null, url=null, language=null, rfNumber=4, rfOrder=3, authorNames=PEI F Y, LIU L J, ZHU H E, journalName=Polymers, refType=null, unstructuredReference=
PEI F Y,
LIU L J,
ZHU H E, et al. Recent advances in lignocellulose-based monomers and their polymerization[J].
Polymers,
2023,
15(4): 829., articleTitle=Recent advances in lignocellulose-based monomers and their polymerization, refAbstract=null), Reference(id=1164877078148162060, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=231, issue=null, pageStart=115988, pageEnd=null, url=null, language=null, rfNumber=5, rfOrder=4, authorNames=IDRIS S N, AMELIA T S M, BHUBALAN K, journalName=Environmental Research, refType=null, unstructuredReference=
IDRIS S N,
AMELIA T S M,
BHUBALAN K, et al. The degradation of single-use plastics and commercially viable bioplastics in the environment: a review[J].
Environmental Research,
2023,
231(Pt 1): 115988., articleTitle=The degradation of single-use plastics and commercially viable bioplastics in the environment: a review, refAbstract=null), Reference(id=1164877078206882317, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=858, issue=null, pageStart=160108, pageEnd=null, url=null, language=null, rfNumber=6, rfOrder=5, authorNames=BACHA A U R, NABI I, ZAHEER M, journalName=The Science of the Total Environment, refType=null, unstructuredReference=
BACHA A U R,
NABI I,
ZAHEER M, et al. Biodegradation of macro- and micro-plastics in environment: a review on mechanism, toxicity, and future perspectives[J].
The Science of the Total Environment,
2023,
858(Pt 3): 160108., articleTitle=Biodegradation of macro- and micro-plastics in environment: a review on mechanism, toxicity, and future perspectives, refAbstract=null), Reference(id=1164877078257213966, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=82, issue=null, pageStart=1028, pageEnd=1040, url=null, language=null, rfNumber=7, rfOrder=6, authorNames=ZIA K M, NOREEN A, ZUBER M, journalName=International Journal of Biological Macromolecules, refType=null, unstructuredReference=
ZIA K M,
NOREEN A,
ZUBER M, et al. Recent developments and future prospects on bio-based polyesters derived from renewable resources: a review[J].
International Journal of Biological Macromolecules,
2016,
82: 1028-1040., articleTitle=Recent developments and future prospects on bio-based polyesters derived from renewable resources: a review, refAbstract=null), Reference(id=1164877078315934223, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=32, issue=S2, pageStart=223, pageEnd=228, url=null, language=null, rfNumber=8, rfOrder=7, authorNames=陈龙, 余强, 庄新姝, journalName=材料导报, refType=null, unstructuredReference=陈龙, 余强, 庄新姝, 等. 木质纤维素类生物基材料研究进展[J].
材料导报,
2018,
32(S2): 223-228., articleTitle=木质纤维素类生物基材料研究进展, refAbstract=null), Reference(id=1164877078370460176, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=32, issue=S2, pageStart=223, pageEnd=228, url=null, language=null, rfNumber=8, rfOrder=8, authorNames=CHEN L, YU Q, ZHUANG X S, journalName=Materials Reports, refType=null, unstructuredReference=
CHEN L,
YU Q,
ZHUANG X S, et al. Research progress in lignocellulose bio-based materials[J].
Materials Reports,
2018,
32(S2): 223-228., articleTitle=null, refAbstract=null), Reference(id=1164877078420791825, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=343, issue=null, pageStart=126123, pageEnd=null, url=null, language=null, rfNumber=9, rfOrder=9, authorNames=ZHAO L, SUN Z F, ZHANG C C, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHAO L,
SUN Z F,
ZHANG C C, et al. Advances in pretreatment of lignocellulosic biomass for bioenergy production: challenges and perspectives[J].
Bioresource Technology,
2022,
343: 126123., articleTitle=Advances in pretreatment of lignocellulosic biomass for bioenergy production: challenges and perspectives, refAbstract=null), Reference(id=1164877078475317778, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=60, issue=null, pageStart=108000, pageEnd=null, url=null, language=null, rfNumber=10, rfOrder=10, authorNames=LIU H, LIU Z H, ZHANG R K, journalName=Biotechnology Advances, refType=null, unstructuredReference=
LIU H,
LIU Z H,
ZHANG R K, et al. Bacterial conversion routes for lignin valorization[J].
Biotechnology Advances,
2022,
60: 108000., articleTitle=Bacterial conversion routes for lignin valorization, refAbstract=null), Reference(id=1164877078546620947, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=null, issue=10, pageStart=1330, pageEnd=1358, url=null, language=null, rfNumber=11, rfOrder=11, authorNames=陈沁, 杜杰毫, 谢海波, journalName=高分子学报, refType=null, unstructuredReference=陈沁, 杜杰毫, 谢海波, 等. 生物基可聚合单体及其聚合物制备与性能研究进展[J].
高分子学报,
2016(10): 1330-1358., articleTitle=生物基可聚合单体及其聚合物制备与性能研究进展, refAbstract=null), Reference(id=1164877078596952596, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=null, issue=10, pageStart=1330, pageEnd=1358, url=null, language=null, rfNumber=11, rfOrder=12, authorNames=CHEN Q, DU J H, XIE H B, journalName=Acta Polymerica Sinica, refType=null, unstructuredReference=
CHEN Q,
DU J H,
XIE H B, et al. Studies on preparation and properties of bio-based polymeric monomers and their bio-based polymers[J].
Acta Polymerica Sinica,
2016(10): 1330-1358., articleTitle=null, refAbstract=null), Reference(id=1164877078651478549, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=25, issue=11, pageStart=105462, pageEnd=null, url=null, language=null, rfNumber=12, rfOrder=13, authorNames=HAN X, LIU J Q, TIAN S, journalName=iScience, refType=null, unstructuredReference=
HAN X,
LIU J Q,
TIAN S, et al. Microbial cell factories for bio-based biodegradable plastics production[J].
iScience,
2022,
25(11): 105462., articleTitle=Microbial cell factories for bio-based biodegradable plastics production, refAbstract=null), Reference(id=1164877078714393110, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=39, issue=5, pageStart=2081, pageEnd=2094, url=null, language=null, rfNumber=13, rfOrder=14, authorNames=支睿, 卢艳波, 王敏, journalName=生物工程学报, refType=null, unstructuredReference=支睿, 卢艳波, 王敏, 等. 生物可降解塑料单体二元羧酸的生物合成研究进展[J].
生物工程学报,
2023,
39(5): 2081-2094., articleTitle=生物可降解塑料单体二元羧酸的生物合成研究进展, refAbstract=null), Reference(id=1164877078768919063, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=39, issue=5, pageStart=2081, pageEnd=2094, url=null, language=null, rfNumber=13, rfOrder=15, authorNames=ZHI R, LU Y B, WANG M, journalName=Chinese Journal of Biotechnology, refType=null, unstructuredReference=
ZHI R,
LU Y B,
WANG M, et al. Recent progress in the biosynthesis of dicarboxylic acids, a monomer of biodegradable plastics[J].
Chinese Journal of Biotechnology,
2023,
39(5): 2081-2094., articleTitle=null, refAbstract=null), Reference(id=1164877078831833624, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=66, issue=null, pageStart=108157, pageEnd=null, url=null, language=null, rfNumber=14, rfOrder=16, authorNames=WANG J, SHIRVANI H, ZHAO H, journalName=Biotechnology Advances, refType=null, unstructuredReference=
WANG J,
SHIRVANI H,
ZHAO H, et al. Lignocellulosic biomass valorization
via bio-photo/electro hybrid catalytic systems[J].
Biotechnology Advances,
2023,
66: 108157., articleTitle=Lignocellulosic biomass valorization
via bio-photo/electro hybrid catalytic systems, refAbstract=null), Reference(id=1164877078890553881, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2024, volume=5, issue=6, pageStart=1264, pageEnd=1278, url=null, language=null, rfNumber=15, rfOrder=17, authorNames=刘宽庆, 张以恒, journalName=合成生物学, refType=null, unstructuredReference=刘宽庆,张以恒. 木质素的生物降解和生物利用 [J].
合成生物学,
2024,
5(6):1264-1278., articleTitle=木质素的生物降解和生物利用, refAbstract=null), Reference(id=1164877078953468442, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2024, volume=5, issue=6, pageStart=1264, pageEnd=1278, url=null, language=null, rfNumber=15, rfOrder=18, authorNames=LIU K Q, ZHANG Y-H P J, journalName=Synthetic Biology Journal, refType=null, unstructuredReference=
LIU K Q,
ZHANG Y-H P J. Biological degradation and utilization of lignin[J].
Synthetic Biology Journal,
2024,
5(6):1264-1278., articleTitle=null, refAbstract=null), Reference(id=1164877079020577307, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2019, volume=37, issue=6, pageStart=107360, pageEnd=null, url=null, language=null, rfNumber=16, rfOrder=19, authorNames=BECKER J, WITTMANN C, journalName=Biotechnology Advances, refType=null, unstructuredReference=
BECKER J,
WITTMANN C. A field of dreams: lignin valorization into chemicals, materials, fuels, and health-care products[J].
Biotechnology Advances,
2019,
37(6): 107360., articleTitle=A field of dreams: lignin valorization into chemicals, materials, fuels, and health-care products, refAbstract=null), Reference(id=1164877079083491868, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2024, volume=22, issue=2, pageStart=119, pageEnd=130, url=null, language=null, rfNumber=17, rfOrder=20, authorNames=曹玉连, 庄伟, 唐成伦, journalName=生物加工过程, refType=null, unstructuredReference=曹玉连, 庄伟, 唐成伦, 等. 木质纤维素预处理实现组分综合利用[J].
生物加工过程,
2024,
22(2): 119-130., articleTitle=木质纤维素预处理实现组分综合利用, refAbstract=null), Reference(id=1164877079154795037, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2024, volume=22, issue=2, pageStart=119, pageEnd=130, url=null, language=null, rfNumber=17, rfOrder=21, authorNames=CAO Y L, ZHUANG W, TANG C L, journalName=Chinese Journal of Bioprocess Engineering, refType=null, unstructuredReference=
CAO Y L,
ZHUANG W,
TANG C L, et al. Advances on comprehensive utilization of lignocellulose through pretreatment technology[J].
Chinese Journal of Bioprocess Engineering,
2024,
22(2): 119-130., articleTitle=null, refAbstract=null), Reference(id=1164877079221903902, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=3, issue=null, pageStart=100035, pageEnd=null, url=null, language=null, rfNumber=18, rfOrder=22, authorNames=ROY R, RAHMAN M S, RAYNIE D E, journalName=Current Research in Green and Sustainable Chemistry, refType=null, unstructuredReference=
ROY R,
RAHMAN M S,
RAYNIE D E. Recent advances of greener pretreatment technologies of lignocellulose[J].
Current Research in Green and Sustainable Chemistry,
2020,
3: 100035., articleTitle=Recent advances of greener pretreatment technologies of lignocellulose, refAbstract=null), Reference(id=1164877079293207071, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=360, issue=null, pageStart=127575, pageEnd=null, url=null, language=null, rfNumber=19, rfOrder=23, authorNames=SOHN Y J, SON J N, LIM H J, journalName=Bioresource Technology, refType=null, unstructuredReference=
SOHN Y J,
SON J N,
LIM H J, et al. Valorization of lignocellulosic biomass for polyhydroxyalkanoate production: status and perspectives[J].
Bioresource Technology,
2022,
360: 127575., articleTitle=Valorization of lignocellulosic biomass for polyhydroxyalkanoate production: status and perspectives, refAbstract=null), Reference(id=1164877079347733024, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=250, issue=null, pageStart=770, pageEnd=776, url=null, language=null, rfNumber=20, rfOrder=24, authorNames=BAI X P, WANG G H, YU Y, journalName=Bioresource Technology, refType=null, unstructuredReference=
BAI X P,
WANG G H,
YU Y, et al. Changes in the physicochemical structure and pyrolysis characteristics of wheat straw after rod-milling pretreatment[J].
Bioresource Technology,
2018,
250: 770-776., articleTitle=Changes in the physicochemical structure and pyrolysis characteristics of wheat straw after rod-milling pretreatment, refAbstract=null), Reference(id=1164877079402258977, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=369, issue=null, pageStart=128328, pageEnd=null, url=null, language=null, rfNumber=21, rfOrder=25, authorNames=DHARMARAJA J, SHOBANA S, ARVINDNARAYAN S, journalName=Bioresource Technology, refType=null, unstructuredReference=
DHARMARAJA J,
SHOBANA S,
ARVINDNARAYAN S, et al. Lignocellulosic biomass conversion
via greener pretreatment methods towards biorefinery applications[J].
Bioresource Technology,
2023,
369: 128328., articleTitle=Lignocellulosic biomass conversion
via greener pretreatment methods towards biorefinery applications, refAbstract=null), Reference(id=1164877079456784930, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=40, issue=null, pageStart=140, pageEnd=150, url=null, language=null, rfNumber=22, rfOrder=26, authorNames=SUBHEDAR P B, RAY P, GOGATE P R, journalName=Ultrasonics Sonochemistry, refType=null, unstructuredReference=
SUBHEDAR P B, RAY P,
GOGATE P R. Intensification of delignification and subsequent hydrolysis for the fermentable sugar production from lignocellulosic biomass using ultrasonic irradiation[J].
Ultrasonics Sonochemistry,
2018,
40(Pt B): 140-150., articleTitle=Intensification of delignification and subsequent hydrolysis for the fermentable sugar production from lignocellulosic biomass using ultrasonic irradiation, refAbstract=null), Reference(id=1164877079523893795, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=334, issue=null, pageStart=125235, pageEnd=null, url=null, language=null, rfNumber=23, rfOrder=27, authorNames=MANKAR A R, PANDEY A, MODAK A, journalName=Bioresource Technology, refType=null, unstructuredReference=
MANKAR A R,
PANDEY A,
MODAK A, et al. Pretreatment of lignocellulosic biomass: a review on recent advances[J].
Bioresource Technology,
2021,
334: 125235., articleTitle=Pretreatment of lignocellulosic biomass: a review on recent advances, refAbstract=null), Reference(id=1164877079595196964, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=361, issue=null, pageStart=127724, pageEnd=null, url=null, language=null, rfNumber=24, rfOrder=28, authorNames=SHANGDIAR S, LIN Y C, PONNUSAMY V K, journalName=Bioresource Technology, refType=null, unstructuredReference=
SHANGDIAR S,
LIN Y C,
PONNUSAMY V K, et al. Pretreatment of lignocellulosic biomass from sugar bagasse under microwave assisted dilute acid hydrolysis for biobutanol production[J].
Bioresource Technology,
2022,
361: 127724., articleTitle=Pretreatment of lignocellulosic biomass from sugar bagasse under microwave assisted dilute acid hydrolysis for biobutanol production, refAbstract=null), Reference(id=1164877079662305829, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=100, issue=null, pageStart=137, pageEnd=144, url=null, language=null, rfNumber=25, rfOrder=29, authorNames=HUANG Y F, CHIUEH P T, KUAN W H, journalName=Energy, refType=null, unstructuredReference=
HUANG Y F,
CHIUEH P T,
KUAN W H, et al. Microwave pyrolysis of lignocellulosic biomass: heating performance and reaction kinetics[J].
Energy,
2016,
100: 137-144., articleTitle=Microwave pyrolysis of lignocellulosic biomass: heating performance and reaction kinetics, refAbstract=null), Reference(id=1164877079716831782, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=332, issue=null, pageStart=704, pageEnd=709, url=null, language=null, rfNumber=26, rfOrder=30, authorNames=SCHNABEL T, HUBER H, GRÜNEWALD T A, journalName=Applied Surface Science, refType=null, unstructuredReference=
SCHNABEL T,
HUBER H,
GRÜNEWALD T A, et al. Changes in mechanical and chemical wood properties by electron beam irradiation[J].
Applied Surface Science,
2015,
332: 704-709., articleTitle=Changes in mechanical and chemical wood properties by electron beam irradiation, refAbstract=null), Reference(id=1164877079762969127, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=10, issue=3, pageStart=1130, pageEnd=null, url=null, language=null, rfNumber=27, rfOrder=31, authorNames=SU X J, ZHANG C Y, LI W J, journalName=Applied Sciences, refType=null, unstructuredReference=
SU X J,
ZHANG C Y,
LI W J, et al. Radiation-induced structural changes of
Miscanthus biomass[J].
Applied Sciences,
2020,
10(3): 1130., articleTitle=Radiation-induced structural changes of
Miscanthus biomass, refAbstract=null), Reference(id=1164877079817495080, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2011, volume=50, issue=19, pageStart=10996, pageEnd=11001, url=null, language=null, rfNumber=28, rfOrder=32, authorNames=KUMAR P, BARRETT D M, DELWICHE M J, journalName=Industrial & Engineering Chemistry Research, refType=null, unstructuredReference=
KUMAR P,
BARRETT D M,
DELWICHE M J, et al. Pulsed electric field pretreatment of switchgrass and wood chip species for biofuel production[J].
Industrial & Engineering Chemistry Research,
2011,
50(19): 10996-11001., articleTitle=Pulsed electric field pretreatment of switchgrass and wood chip species for biofuel production, refAbstract=null), Reference(id=1164877079872021033, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=120, issue=null, pageStart=467, pageEnd=483, url=null, language=null, rfNumber=29, rfOrder=33, authorNames=KOVAČIĆ Đ, RUPČIĆ S, KRALIK D, journalName=Waste Management, refType=null, unstructuredReference=
KOVAČIĆ Đ,
RUPČIĆ S,
KRALIK D, et al. Pulsed electric field: an emerging pretreatment technology in a biogas production[J].
Waste Management,
2021,
120: 467-483., articleTitle=Pulsed electric field: an emerging pretreatment technology in a biogas production, refAbstract=null), Reference(id=1164877079922352682, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=8, issue=null, pageStart=252, pageEnd=null, url=null, language=null, rfNumber=30, rfOrder=34, authorNames=ESCOBAR E L N, SILVA T A DA, PIRICH C L, journalName=Frontiers in Bioengineering and Biotechnology, refType=null, unstructuredReference=
ESCOBAR E L N,
SILVA T A DA,
PIRICH C L, et al. Supercritical fluids: a promising technique for biomass pretreatment and fractionation[J].
Frontiers in Bioengineering and Biotechnology,
2020,
8: 252., articleTitle=Supercritical fluids: a promising technique for biomass pretreatment and fractionation, refAbstract=null), Reference(id=1164877079985267243, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=10, issue=1, pageStart=14, pageEnd=31, url=null, language=null, rfNumber=31, rfOrder=35, authorNames=VANNESTE J, ENNAERT T, VANHULSEL A, journalName=ChemSusChem, refType=null, unstructuredReference=
VANNESTE J,
ENNAERT T,
VANHULSEL A, et al. Unconventional pretreatment of lignocellulose with low-temperature plasma[J].
ChemSusChem,
2017,
10(1): 14-31., articleTitle=Unconventional pretreatment of lignocellulose with low-temperature plasma, refAbstract=null), Reference(id=1164877080052376108, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=41, issue=46, pageStart=21678, pageEnd=21684, url=null, language=null, rfNumber=32, rfOrder=36, authorNames=GONZALES R R, SIVAGURUNATHAN P, KIM S H, journalName=International Journal of Hydrogen Energy, refType=null, unstructuredReference=
GONZALES R R,
SIVAGURUNATHAN P,
KIM S H. Effect of severity on dilute acid pretreatment of lignocellulosic biomass and the following hydrogen fermentation[J].
International Journal of Hydrogen Energy,
2016,
41(46): 21678-21684., articleTitle=Effect of severity on dilute acid pretreatment of lignocellulosic biomass and the following hydrogen fermentation, refAbstract=null), Reference(id=1164877080106902061, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=201, issue=null, pageStart=182, pageEnd=190, url=null, language=null, rfNumber=33, rfOrder=37, authorNames=BOLADO-RODRÍGUEZ S, TOQUERO C, MARTÍN-JUÁREZ J, journalName=Bioresource Technology, refType=null, unstructuredReference=
BOLADO-RODRÍGUEZ S,
TOQUERO C,
MARTÍN-JUÁREZ J, et al. Effect of thermal, acid, alkaline and alkaline-peroxide pretreatments on the biochemical methane potential and kinetics of the anaerobic digestion of wheat straw and sugarcane bagasse[J].
Bioresource Technology,
2016,
201: 182-190., articleTitle=Effect of thermal, acid, alkaline and alkaline-peroxide pretreatments on the biochemical methane potential and kinetics of the anaerobic digestion of wheat straw and sugarcane bagasse, refAbstract=null), Reference(id=1164877080174010926, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=267, issue=null, pageStart=71, pageEnd=76, url=null, language=null, rfNumber=34, rfOrder=38, authorNames=DONG L L, CAO G L, ZHAO L, journalName=Bioresource Technology, refType=null, unstructuredReference=
DONG L L,
CAO G L,
ZHAO L, et al. Alkali/urea pretreatment of rice straw at low temperature for enhanced biological hydrogen production[J].
Bioresource Technology,
2018,
267: 71-76., articleTitle=Alkali/urea pretreatment of rice straw at low temperature for enhanced biological hydrogen production, refAbstract=null), Reference(id=1164877080257897007, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=263, issue=null, pageStart=601, pageEnd=612, url=null, language=null, rfNumber=35, rfOrder=39, authorNames=SANTOS L C D, ADARME O F H, BAÊTA B E L, journalName=Bioresource Technology, refType=null, unstructuredReference=
SANTOS L C D,
ADARME O F H,
BAÊTA B E L, et al. Production of biogas (methane and hydrogen) from anaerobic digestion of hemicellulosic hydrolysate generated in the oxidative pretreatment of coffee husks[J].
Bioresource Technology,
2018,
263: 601-612., articleTitle=Production of biogas (methane and hydrogen) from anaerobic digestion of hemicellulosic hydrolysate generated in the oxidative pretreatment of coffee husks, refAbstract=null), Reference(id=1164877080316617264, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=155, issue=null, pageStart=34, pageEnd=40, url=null, language=null, rfNumber=36, rfOrder=40, authorNames=ZHAO C, DING W M, CHEN F, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHAO C,
DING W M,
CHEN F, et al. Effects of compositional changes of AFEX-treated and H-AFEX-treated corn stover on enzymatic digestibility[J].
Bioresource Technology,
2014,
155: 34-40., articleTitle=Effects of compositional changes of AFEX-treated and H-AFEX-treated corn stover on enzymatic digestibility, refAbstract=null), Reference(id=1164877080371143217, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=322, issue=null, pageStart=124522, pageEnd=null, url=null, language=null, rfNumber=37, rfOrder=41, authorNames=ZHANG J X, ZHANG X, YANG M K, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHANG J X,
ZHANG X,
YANG M K, et al. Transforming lignocellulosic biomass into biofuels enabled by ionic liquid pretreatment[J].
Bioresource Technology,
2021,
322: 124522., articleTitle=Transforming lignocellulosic biomass into biofuels enabled by ionic liquid pretreatment, refAbstract=null), Reference(id=1164877080421474866, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=199, issue=null, pageStart=106244, pageEnd=null, url=null, language=null, rfNumber=38, rfOrder=42, authorNames=KUMAR B, BHARDWAJ N, AGRAWAL K, journalName=Fuel Processing Technology, refType=null, unstructuredReference=
KUMAR B,
BHARDWAJ N,
AGRAWAL K, et al. Current perspective on pretreatment technologies using lignocellulosic biomass: an emerging biorefinery concept[J].
Fuel Processing Technology,
2020,
199: 106244., articleTitle=Current perspective on pretreatment technologies using lignocellulosic biomass: an emerging biorefinery concept, refAbstract=null), Reference(id=1164877080480195123, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2003, volume=null, issue=1, pageStart=70, pageEnd=71, url=null, language=null, rfNumber=39, rfOrder=43, authorNames=ABBOTT A P, CAPPER G, DAVIES D L, journalName=Chemical Communications, refType=null, unstructuredReference=
ABBOTT A P,
CAPPER G,
DAVIES D L, et al. Novel solvent properties of choline chloride/urea mixtures[J].
Chemical Communications,
2003(1): 70-71., articleTitle=Novel solvent properties of choline chloride/urea mixtures, refAbstract=null), Reference(id=1164877080555692596, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2019, volume=24, issue=22, pageStart=4012, pageEnd=null, url=null, language=null, rfNumber=40, rfOrder=44, authorNames=KALHOR P, GHANDI K, journalName=Molecules, refType=null, unstructuredReference=
KALHOR P,
GHANDI K. Deep eutectic solvents for pretreatment, extraction, and catalysis of biomass and food waste[J].
Molecules,
2019,
24(22): 4012., articleTitle=Deep eutectic solvents for pretreatment, extraction, and catalysis of biomass and food waste, refAbstract=null), Reference(id=1164877080622801461, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=18, issue=11, pageStart=768, pageEnd=778, url=null, language=null, rfNumber=41, rfOrder=45, authorNames=ANDLAR M, REZIĆ T, MARĐETKO N, journalName=Engineering in Life Sciences, refType=null, unstructuredReference=
ANDLAR M,
REZIĆ T,
MARĐETKO N, et al. Lignocellulose degradation: an overview of fungi and fungal enzymes involved in lignocellulose degradation[J].
Engineering in Life Sciences,
2018,
18(11): 768-778., articleTitle=Lignocellulose degradation: an overview of fungi and fungal enzymes involved in lignocellulose degradation, refAbstract=null), Reference(id=1164877080681521718, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=259, issue=null, pageStart=18, pageEnd=23, url=null, language=null, rfNumber=42, rfOrder=46, authorNames=XU W Y, FU S F, YANG Z M, journalName=Bioresource Technology, refType=null, unstructuredReference=
XU W Y,
FU S F,
YANG Z M, et al. Improved methane production from corn straw by microaerobic pretreatment with a pure bacteria system[J].
Bioresource Technology,
2018,
259: 18-23., articleTitle=Improved methane production from corn straw by microaerobic pretreatment with a pure bacteria system, refAbstract=null), Reference(id=1164877080757019191, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=114, issue=18, pageStart=4709, pageEnd=4714, url=null, language=null, rfNumber=43, rfOrder=47, authorNames=LI H J, YELLE D J, LI C, journalName=Proceedings of the National Academy of Sciences of the United States of America, refType=null, unstructuredReference=
LI H J,
YELLE D J,
LI C, et al. Lignocellulose pretreatment in a fungus-cultivating termite[J].
Proceedings of the National Academy of Sciences of the United States of America,
2017,
114(18): 4709-4714., articleTitle=Lignocellulose pretreatment in a fungus-cultivating termite, refAbstract=null), Reference(id=1164877080815739448, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2011, volume=29, issue=6, pageStart=675, pageEnd=685, url=null, language=null, rfNumber=44, rfOrder=48, authorNames=AGBOR V B, CICEK N, SPARLING R, journalName=Biotechnology Advances, refType=null, unstructuredReference=
AGBOR V B,
CICEK N,
SPARLING R, et al. Biomass pretreatment: fundamentals toward application[J].
Biotechnology Advances,
2011,
29(6): 675-685., articleTitle=Biomass pretreatment: fundamentals toward application, refAbstract=null), Reference(id=1164877080870265401, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=92, issue=null, pageStart=165, pageEnd=173, url=null, language=null, rfNumber=45, rfOrder=49, authorNames=SOARES RODRIGUES C I, JACKSON J J, MONTROSS M D, journalName=Industrial Crops and Products, refType=null, unstructuredReference=
SOARES RODRIGUES C I,
JACKSON J J,
MONTROSS M D. A molar basis comparison of calcium hydroxide, sodium hydroxide, and potassium hydroxide on the pretreatment of switchgrass and miscanthus under high solids conditions[J].
Industrial Crops and Products,
2016,
92: 165-173., articleTitle=A molar basis comparison of calcium hydroxide, sodium hydroxide, and potassium hydroxide on the pretreatment of switchgrass and miscanthus under high solids conditions, refAbstract=null), Reference(id=1164877080920597050, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2019, volume=272, issue=null, pageStart=326, pageEnd=336, url=null, language=null, rfNumber=46, rfOrder=50, authorNames=MOKOMELE T, COSTA SOUSA L DA, BALAN V, journalName=Bioresource Technology, refType=null, unstructuredReference=
MOKOMELE T,
COSTA SOUSA L DA,
BALAN V, et al. Incorporating anaerobic co-digestion of steam exploded or ammonia fiber expansion pretreated sugarcane residues with manure into a sugarcane-based bioenergy-livestock nexus[J].
Bioresource Technology,
2019,
272: 326-336., articleTitle=Incorporating anaerobic co-digestion of steam exploded or ammonia fiber expansion pretreated sugarcane residues with manure into a sugarcane-based bioenergy-livestock nexus, refAbstract=null), Reference(id=1164877080983511611, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=245, issue=null, pageStart=419, pageEnd=425, url=null, language=null, rfNumber=47, rfOrder=51, authorNames=YAN X, WANG Z R, ZHANG K J, journalName=Bioresource Technology, refType=null, unstructuredReference=
YAN X,
WANG Z R,
ZHANG K J, et al. Bacteria-enhanced dilute acid pretreatment of lignocellulosic biomass[J].
Bioresource Technology,
2017,
245(Pt A): 419-425., articleTitle=Bacteria-enhanced dilute acid pretreatment of lignocellulosic biomass, refAbstract=null), Reference(id=1164877081033843260, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=19, issue=20, pageStart=4939, pageEnd=4955, url=null, language=null, rfNumber=48, rfOrder=52, authorNames=LIU Z H, OLSON M L, SHINDE S, journalName=Green Chemistry, refType=null, unstructuredReference=
LIU Z H,
OLSON M L,
SHINDE S, et al. Synergistic maximization of the carbohydrate output and lignin processability by combinatorial pretreatment[J].
Green Chemistry,
2017,
19(20): 4939-4955., articleTitle=Synergistic maximization of the carbohydrate output and lignin processability by combinatorial pretreatment, refAbstract=null), Reference(id=1164877081105146429, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=37, issue=1, pageStart=15, pageEnd=29, url=null, language=null, rfNumber=49, rfOrder=53, authorNames=杨莉, 谭丽萍, 刘同军, journalName=生物工程学报, refType=null, unstructuredReference=杨莉, 谭丽萍, 刘同军. 木质纤维素预处理抑制物产生及脱除方法的研究进展[J].
生物工程学报,
2021,
37(1): 15-29., articleTitle=木质纤维素预处理抑制物产生及脱除方法的研究进展, refAbstract=null), Reference(id=1164877081168060990, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=37, issue=1, pageStart=15, pageEnd=29, url=null, language=null, rfNumber=49, rfOrder=54, authorNames=YANG L, TAN L P, LIU T J, journalName=Chinese Journal of Biotechnology, refType=null, unstructuredReference=
YANG L,
TAN L P,
LIU T J. Progress in detoxification of inhibitors generated during lignocellulose pretreatment[J].
Chinese Journal of Biotechnology,
2021,
37(1): 15-29., articleTitle=null, refAbstract=null), Reference(id=1164877081230975551, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2011, volume=108, issue=9, pageStart=2053, pageEnd=2060, url=null, language=null, rfNumber=50, rfOrder=55, authorNames=CARTER B, SQUILLACE P, GILCREASE P C, journalName=Biotechnology and Bioengineering, refType=null, unstructuredReference=
CARTER B,
SQUILLACE P,
GILCREASE P C, et al. Detoxification of a lignocellulosic biomass slurry by soluble polyelectrolyte adsorption for improved fermentation efficiency[J].
Biotechnology and Bioengineering,
2011,
108(9): 2053-2060., articleTitle=Detoxification of a lignocellulosic biomass slurry by soluble polyelectrolyte adsorption for improved fermentation efficiency, refAbstract=null), Reference(id=1164877081293890112, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=197, issue=null, pageStart=276, pageEnd=283, url=null, language=null, rfNumber=51, rfOrder=56, authorNames=ZHANG Y Q, LI M, WANG Y F, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHANG Y Q,
LI M,
WANG Y F, et al. Simultaneous concentration and detoxification of lignocellulosic hydrolyzates by vacuum membrane distillation coupled with adsorption[J].
Bioresource Technology,
2015,
197: 276-283., articleTitle=Simultaneous concentration and detoxification of lignocellulosic hydrolyzates by vacuum membrane distillation coupled with adsorption, refAbstract=null), Reference(id=1164877081377776193, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=93, issue=10, pageStart=3011, pageEnd=3017, url=null, language=null, rfNumber=52, rfOrder=57, authorNames=HAQ I, ARSHAD Y, NAWAZ A, journalName=Journal of Chemical Technology & Biotechnology, refType=null, unstructuredReference=HAQ I,
ARSHAD Y,
NAWAZ A, et al. Removal of phenolic compounds through overliming for enhanced saccharification of wheat straw[J].
Journal of Chemical Technology & Biotechnology,
2018,
93(10): 3011-3017., articleTitle=Removal of phenolic compounds through overliming for enhanced saccharification of wheat straw, refAbstract=null), Reference(id=1164877081449079362, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=166, issue=null, pageStart=559, pageEnd=565, url=null, language=null, rfNumber=53, rfOrder=58, authorNames=SOUDHAM V P, BRANDBERG T, MIKKOLA J P, journalName=Bioresource Technology, refType=null, unstructuredReference=
SOUDHAM V P,
BRANDBERG T,
MIKKOLA J P, et al. Detoxification of acid pretreated spruce hydrolysates with ferrous sulfate and hydrogen peroxide improves enzymatic hydrolysis and fermentation[J].
Bioresource Technology,
2014,
166: 559-565., articleTitle=Detoxification of acid pretreated spruce hydrolysates with ferrous sulfate and hydrogen peroxide improves enzymatic hydrolysis and fermentation, refAbstract=null), Reference(id=1164877081516188227, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=186, issue=null, pageStart=106, pageEnd=113, url=null, language=null, rfNumber=54, rfOrder=59, authorNames=XIE R, TU M B, CARVIN J, journalName=Bioresource Technology, refType=null, unstructuredReference=
XIE R,
TU M B,
CARVIN J, et al. Detoxification of biomass hydrolysates with nucleophilic amino acids enhances alcoholic fermentation[J].
Bioresource Technology,
2015,
186: 106-113., articleTitle=Detoxification of biomass hydrolysates with nucleophilic amino acids enhances alcoholic fermentation, refAbstract=null), Reference(id=1164877081591685700, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=135, issue=null, pageStart=109490, pageEnd=null, url=null, language=null, rfNumber=55, rfOrder=60, authorNames=TRAMONTINA R, BRENELLI L B, SOUSA A, journalName=Enzyme and Microbial Technology, refType=null, unstructuredReference=
TRAMONTINA R,
BRENELLI L B,
SOUSA A, et al. Designing a cocktail containing redox enzymes to improve hemicellulosic hydrolysate fermentability by microorganisms[J].
Enzyme and Microbial Technology,
2020,
135: 109490., articleTitle=Designing a cocktail containing redox enzymes to improve hemicellulosic hydrolysate fermentability by microorganisms, refAbstract=null), Reference(id=1164877081662988871, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=104, issue=8, pageStart=3473, pageEnd=3492, url=null, language=null, rfNumber=56, rfOrder=61, authorNames=LIU Z L, MA M G, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
LIU Z L,
MA M G. Pathway-based signature transcriptional profiles as tolerance phenotypes for the adapted industrial yeast
Saccharomyces cerevisiae resistant to furfural and HMF[J].
Applied Microbiology and Biotechnology,
2020,
104(8): 3473-3492., articleTitle=Pathway-based signature transcriptional profiles as tolerance phenotypes for the adapted industrial yeast
Saccharomyces cerevisiae resistant to furfural and HMF, refAbstract=null), Reference(id=1164877081734292040, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=53, issue=42, pageStart=16494, pageEnd=16501, url=null, language=null, rfNumber=57, rfOrder=62, authorNames=SANTOS J C, MARTON J M, FELIPE M G A, journalName=Industrial & Engineering Chemistry Research, refType=null, unstructuredReference=
SANTOS J C,
MARTON J M,
FELIPE M G A. Continuous system of combined columns of ion exchange resins and activated charcoal as a new approach for the removal of toxics from sugar cane bagasse hemicellulosic hydrolysate[J].
Industrial & Engineering Chemistry Research,
2014,
53(42): 16494-16501., articleTitle=Continuous system of combined columns of ion exchange resins and activated charcoal as a new approach for the removal of toxics from sugar cane bagasse hemicellulosic hydrolysate, refAbstract=null), Reference(id=1164877081780429386, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=550, issue=null, pageStart=113551, pageEnd=null, url=null, language=null, rfNumber=58, rfOrder=63, authorNames=LI X, XU Y, ALORKU K, journalName=Molecular Catalysis, refType=null, unstructuredReference=
LI X,
XU Y,
ALORKU K, et al. A review of lignin-first reductive catalytic fractionation of lignocellulose[J].
Molecular Catalysis,
2023,
550: 113551., articleTitle=A review of lignin-first reductive catalytic fractionation of lignocellulose, refAbstract=null), Reference(id=1164877081834955341, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=17, issue=3, pageStart=1492, pageEnd=1499, url=null, language=null, rfNumber=59, rfOrder=64, authorNames=PARSELL T, YOHE S, DEGENSTEIN J, journalName=Green Chemistry, refType=null, unstructuredReference=
PARSELL T,
YOHE S,
DEGENSTEIN J, et al. A synergistic biorefinery based on catalytic conversion of lignin prior to cellulose starting from lignocellulosic biomass[J].
Green Chemistry,
2015,
17(3): 1492-1499., articleTitle=A synergistic biorefinery based on catalytic conversion of lignin prior to cellulose starting from lignocellulosic biomass, refAbstract=null), Reference(id=1164877081914647118, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=62, issue=32, pageStart=null, pageEnd=null, url=null, language=null, rfNumber=60, rfOrder=65, authorNames=LI Y L, YU Y Y, LOU Y H, journalName=Angewandte Chemie International Edition, refType=null, unstructuredReference=
LI Y L,
YU Y Y,
LOU Y H, et al. Hydrogen-transfer reductive catalytic fractionation of lignocellulose: high monomeric yield with switchable selectivity[J].
Angewandte Chemie International Edition,
2023,
62(32): e202307116., articleTitle=Hydrogen-transfer reductive catalytic fractionation of lignocellulose: high monomeric yield with switchable selectivity, refAbstract=null), Reference(id=1164877081969173072, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=11, issue=12, pageStart=4517, pageEnd=4522, url=null, language=null, rfNumber=61, rfOrder=66, authorNames=FACAS G G, BRANDNER D G, BUSSARD J R, journalName=ACS Sustainable Chemistry & Engineering, refType=null, unstructuredReference=
FACAS G G,
BRANDNER D G,
BUSSARD J R, et al. Interdependence of solvent and catalyst selection on low pressure hydrogen-free reductive catalytic fractionation[J].
ACS Sustainable Chemistry & Engineering,
2023,
11(12): 4517-4522., articleTitle=Interdependence of solvent and catalyst selection on low pressure hydrogen-free reductive catalytic fractionation, refAbstract=null), Reference(id=1164877082036281937, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=376, issue=null, pageStart=128887, pageEnd=null, url=null, language=null, rfNumber=62, rfOrder=67, authorNames=ZHAN Q W, LIN Q X, WU Y, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHAN Q W,
LIN Q X,
WU Y, et al. A fractionation strategy of cellulose, hemicellulose, and lignin from wheat straw
via the biphasic pretreatment for biomass valorization[J].
Bioresource Technology,
2023,
376: 128887., articleTitle=A fractionation strategy of cellulose, hemicellulose, and lignin from wheat straw
via the biphasic pretreatment for biomass valorization, refAbstract=null), Reference(id=1164877082090807890, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=11, issue=16, pageStart=2758, pageEnd=2765, url=null, language=null, rfNumber=63, rfOrder=68, authorNames=GUO T Y, LI X C, LIU X H, journalName=ChemSusChem, refType=null, unstructuredReference=
GUO T Y,
LI X C,
LIU X H, et al. Catalytic transformation of lignocellulosic biomass into arenes, 5-hydroxymethylfurfural, and furfural[J].
ChemSusChem,
2018,
11(16): 2758-2765., articleTitle=Catalytic transformation of lignocellulosic biomass into arenes, 5-hydroxymethylfurfural, and furfural, refAbstract=null), Reference(id=1164877082145333843, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=1, issue=null, pageStart=82, pageEnd=92, url=null, language=null, rfNumber=64, rfOrder=69, authorNames=SUN Z H, BOTTARI G, AFANASENKO A, journalName=Nature Catalysis, refType=null, unstructuredReference=
SUN Z H,
BOTTARI G,
AFANASENKO A, et al. Complete lignocellulose conversion with integrated catalyst recycling yielding valuable aromatics and fuels[J].
Nature Catalysis,
2018,
1: 82-92., articleTitle=Complete lignocellulose conversion with integrated catalyst recycling yielding valuable aromatics and fuels, refAbstract=null), Reference(id=1164877082199859796, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=37, issue=1, pageStart=16, pageEnd=null, url=null, language=null, rfNumber=65, rfOrder=70, authorNames=LU J S, LI J W, GAO H, journalName=World Journal of Microbiology & Biotechnology, refType=null, unstructuredReference=
LU J S,
LI J W,
GAO H, et al. Recent progress on bio-succinic acid production from lignocellulosic biomass[J].
World Journal of Microbiology & Biotechnology,
2021,
37(1): 16., articleTitle=Recent progress on bio-succinic acid production from lignocellulosic biomass, refAbstract=null), Reference(id=1164877082283745877, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2019, volume=12, issue=null, pageStart=35, pageEnd=null, url=null, language=null, rfNumber=66, rfOrder=71, authorNames=LIU S Y, LIU Y J, FENG Y G, journalName=Biotechnology for Biofuels, refType=null, unstructuredReference=
LIU S Y,
LIU Y J,
FENG Y G, et al. Construction of consolidated bio-saccharification biocatalyst and process optimization for highly efficient lignocellulose solubilization[J].
Biotechnology for Biofuels,
2019,
12: 35., articleTitle=Construction of consolidated bio-saccharification biocatalyst and process optimization for highly efficient lignocellulose solubilization, refAbstract=null), Reference(id=1164877082367631958, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=10, issue=null, pageStart=843887, pageEnd=null, url=null, language=null, rfNumber=67, rfOrder=72, authorNames=LIU X T, ZHAO G, SUN S J, journalName=Frontiers in Bioengineering and Biotechnology, refType=null, unstructuredReference=
LIU X T,
ZHAO G,
SUN S J, et al. Biosynthetic pathway and metabolic engineering of succinic acid[J].
Frontiers in Bioengineering and Biotechnology,
2022,
10: 843887., articleTitle=Biosynthetic pathway and metabolic engineering of succinic acid, refAbstract=null), Reference(id=1164877082422157914, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=42, issue=null, pageStart=54, pageEnd=66, url=null, language=null, rfNumber=68, rfOrder=73, authorNames=AHN J H, JANG Y S, LEE S Y, journalName=Current Opinion in Biotechnology, refType=null, unstructuredReference=
AHN J H,
JANG Y S,
LEE S Y. Production of succinic acid by metabolically engineered microorganisms[J].
Current Opinion in Biotechnology,
2016,
42: 54-66., articleTitle=Production of succinic acid by metabolically engineered microorganisms, refAbstract=null), Reference(id=1164877082493461086, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=360, issue=null, pageStart=127513, pageEnd=null, url=null, language=null, rfNumber=69, rfOrder=74, authorNames=NARISETTY V, OKIBE M C, AMULYA K, journalName=Bioresource Technology, refType=null, unstructuredReference=
NARISETTY V,
OKIBE M C,
AMULYA K, et al. Technological advancements in valorization of second generation (2G) feedstocks for bio-based succinic acid production[J].
Bioresource Technology,
2022,
360: 127513., articleTitle=Technological advancements in valorization of second generation (2G) feedstocks for bio-based succinic acid production, refAbstract=null), Reference(id=1164877082560569952, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=35, issue=8, pageStart=1040, pageEnd=1048, url=null, language=null, rfNumber=70, rfOrder=75, authorNames=ZHU L W, TANG Y J, journalName=Biotechnology Advances, refType=null, unstructuredReference=
ZHU L W,
TANG Y J. Current advances of succinate biosynthesis in metabolically engineered
Escherichia coli [J].
Biotechnology Advances,
2017,
35(8): 1040-1048., articleTitle=Current advances of succinate biosynthesis in metabolically engineered
Escherichia coli, refAbstract=null), Reference(id=1164877082640261730, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=1997, volume=63-65, issue=null, pageStart=153, pageEnd=158, url=null, language=null, rfNumber=71, rfOrder=76, authorNames=STOLS L, KULKARNI G, HARRIS B G, journalName=Applied Biochemistry and Biotechnology, refType=null, unstructuredReference=
STOLS L,
KULKARNI G,
HARRIS B G, et al. Expression of
Ascaris suum malic enzyme in a mutant
Escherichia coli allows production of succinic acid from glucose[J].
Applied Biochemistry and Biotechnology,
1997,
63-65: 153-158., articleTitle=Expression of
Ascaris suum malic enzyme in a mutant
Escherichia coli allows production of succinic acid from glucose, refAbstract=null), Reference(id=1164877082698981991, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=163, issue=null, pageStart=100, pageEnd=105, url=null, language=null, rfNumber=72, rfOrder=77, authorNames=CHEN C X, DING S P, WANG D Z, journalName=Bioresource Technology, refType=null, unstructuredReference=
CHEN C X,
DING S P,
WANG D Z, et al. Simultaneous saccharification and fermentation of cassava to succinic acid by
Escherichia coli NZN111[J].
Bioresource Technology,
2014,
163: 100-105., articleTitle=Simultaneous saccharification and fermentation of cassava to succinic acid by
Escherichia coli NZN111, refAbstract=null), Reference(id=1164877082770285162, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2002, volume=28, issue=6, pageStart=325, pageEnd=332, url=null, language=null, rfNumber=73, rfOrder=78, authorNames=VEMURI G N, EITEMAN M A, ALTMAN E, journalName=Journal of Industrial Microbiology & Biotechnology, refType=null, unstructuredReference=
VEMURI G N,
EITEMAN M A,
ALTMAN E. Succinate production in dual-phase
Escherichia coli fermentations depends on the time of transition from aerobic to anaerobic conditions[J].
Journal of Industrial Microbiology & Biotechnology,
2002,
28(6): 325-332., articleTitle=Succinate production in dual-phase
Escherichia coli fermentations depends on the time of transition from aerobic to anaerobic conditions, refAbstract=null), Reference(id=1164877082837394028, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2011, volume=86, issue=4, pageStart=512, pageEnd=518, url=null, language=null, rfNumber=74, rfOrder=79, authorNames=WANG D, LI Q, SONG Z Y, journalName=Journal of Chemical Technology & Biotechnology, refType=null, unstructuredReference=
WANG D,
LI Q,
SONG Z Y, et al. High cell density fermentation
via a metabolically engineered
Escherichia coli for the enhanced production of succinic acid[J].
Journal of Chemical Technology & Biotechnology,
2011,
86(4): 512-518., articleTitle=High cell density fermentation
via a metabolically engineered
Escherichia coli for the enhanced production of succinic acid, refAbstract=null), Reference(id=1164877082896114287, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=91, issue=null, pageStart=240, pageEnd=249, url=null, language=null, rfNumber=75, rfOrder=80, authorNames=MA J F, LI F, LIU R M, journalName=Biochemical Engineering Journal, refType=null, unstructuredReference=
MA J F,
LI F,
LIU R M, et al. Succinic acid production from sucrose and molasses by metabolically engineered
E.
coli using a cell surface display system[J].
Biochemical Engineering Journal,
2014,
91: 240-249., articleTitle=Succinic acid production from sucrose and molasses by metabolically engineered
E.
coli using a cell surface display system, refAbstract=null), Reference(id=1164877082963223153, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=40, issue=null, pageStart=157, pageEnd=164, url=null, language=null, rfNumber=76, rfOrder=81, authorNames=CHUNG S C, PARK J S, YUN J E, journalName=Metabolic Engineering, refType=null, unstructuredReference=
CHUNG S C,
PARK J S,
YUN J E, et al. Improvement of succinate production by release of end-product inhibition in
Corynebacterium glutamicum [J].
Metabolic Engineering,
2017,
40: 157-164., articleTitle=Improvement of succinate production by release of end-product inhibition in
Corynebacterium glutamicum, refAbstract=null), Reference(id=1164877083047109235, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2008, volume=81, issue=3, pageStart=459, pageEnd=464, url=null, language=null, rfNumber=77, rfOrder=82, authorNames=OKINO S, NOBURYU R, SUDA M, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
OKINO S,
NOBURYU R,
SUDA M, et al. An efficient succinic acid production process in a metabolically engineered
Corynebacterium glutamicum strain[J].
Applied Microbiology and Biotechnology,
2008,
81(3): 459-464., articleTitle=An efficient succinic acid production process in a metabolically engineered
Corynebacterium glutamicum strain, refAbstract=null), Reference(id=1164877083114218101, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=156, issue=null, pageStart=232, pageEnd=239, url=null, language=null, rfNumber=78, rfOrder=83, authorNames=YAN D J, WANG C X, ZHOU J M, journalName=Bioresource Technology, refType=null, unstructuredReference=
YAN D J,
WANG C X,
ZHOU J M, et al. Construction of reductive pathway in
Saccharomyces cerevisiae for effective succinic acid fermentation at low pH value[J].
Bioresource Technology,
2014,
156: 232-239., articleTitle=Construction of reductive pathway in
Saccharomyces cerevisiae for effective succinic acid fermentation at low pH value, refAbstract=null), Reference(id=1164877083172938358, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=14, issue=1, pageStart=8480, pageEnd=null, url=null, language=null, rfNumber=79, rfOrder=84, authorNames=CUI Z Y, ZHONG Y T, SUN Z J, journalName=Nature Communications, refType=null, unstructuredReference=
CUI Z Y,
ZHONG Y T,
SUN Z J, et al. Reconfiguration of the reductive TCA cycle enables high-level succinic acid production by
Yarrowia lipolytica [J].
Nature Communications,
2023,
14(1): 8480., articleTitle=Reconfiguration of the reductive TCA cycle enables high-level succinic acid production by
Yarrowia lipolytica, refAbstract=null), Reference(id=1164877083240047224, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=83, issue=17, pageStart=null, pageEnd=null, url=null, language=null, rfNumber=80, rfOrder=85, authorNames=GUARNIERI M T, CHOU Y C, SALVACHÚA D, journalName=Applied and Environmental Microbiology, refType=null, unstructuredReference=
GUARNIERI M T,
CHOU Y C,
SALVACHÚA D, et al. Metabolic engineering of
Actinobacillus succinogenes provides insights into succinic acid biosynthesis[J].
Applied and Environmental Microbiology,
2017,
83(17): e00996-17., articleTitle=Metabolic engineering of
Actinobacillus succinogenes provides insights into succinic acid biosynthesis, refAbstract=null), Reference(id=1164877083315544698, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=9, issue=1, pageStart=179, pageEnd=null, url=null, language=null, rfNumber=81, rfOrder=86, authorNames=GAO C J, YANG X F, WANG H M, journalName=Biotechnology for Biofuels, refType=null, unstructuredReference=
GAO C J,
YANG X F,
WANG H M, et al. Robust succinic acid production from crude glycerol using engineered
Yarrowia lipolytica [J].
Biotechnology for Biofuels,
2016,
9(1): 179., articleTitle=Robust succinic acid production from crude glycerol using engineered
Yarrowia lipolytica, refAbstract=null), Reference(id=1164877083403625086, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2010, volume=101, issue=20, pageStart=7889, pageEnd=7894, url=null, language=null, rfNumber=82, rfOrder=87, authorNames=ZHENG P, FANG L, XU Y, journalName=Bioresource Technology, refType=null, unstructuredReference=
ZHENG P,
FANG L,
XU Y, et al. Succinic acid production from corn stover by simultaneous saccharification and fermentation using
Actinobacillus succinogenes [J].
Bioresource Technology,
2010,
101(20): 7889-7894., articleTitle=Succinic acid production from corn stover by simultaneous saccharification and fermentation using
Actinobacillus succinogenes, refAbstract=null), Reference(id=1164877083462345346, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2013, volume=110, issue=10, pageStart=4021, pageEnd=4026, url=null, language=null, rfNumber=83, rfOrder=88, authorNames=WANG X, YOMANO L P, LEE J Y, journalName=Proceedings of the National Academy of Sciences of the United States of America, refType=null, unstructuredReference=
WANG X,
YOMANO L P,
LEE J Y, et al. Engineering furfural tolerance in
Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals[J].
Proceedings of the National Academy of Sciences of the United States of America,
2013,
110(10): 4021-4026., articleTitle=Engineering furfural tolerance in
Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals, refAbstract=null), Reference(id=1164877083542037127, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=8, issue=24, pageStart=9035, pageEnd=9045, url=null, language=null, rfNumber=84, rfOrder=89, authorNames=LU J S, LV Y, JIANG Y J, journalName=ACS Sustainable Chemistry & Engineering, refType=null, unstructuredReference=
LU J S,
LV Y,
JIANG Y J, et al. Consolidated bioprocessing of hemicellulose-enriched lignocellulose to succinic acid through a microbial cocultivation system[J].
ACS Sustainable Chemistry & Engineering,
2020,
8(24): 9035-9045., articleTitle=Consolidated bioprocessing of hemicellulose-enriched lignocellulose to succinic acid through a microbial cocultivation system, refAbstract=null), Reference(id=1164877083604951690, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2005, volume=16, issue=5, pageStart=577, pageEnd=583, url=null, language=null, rfNumber=85, rfOrder=90, authorNames=LYND L R, VAN ZYL W H, MCBRIDE J E, journalName=Current Opinion in Biotechnology, refType=null, unstructuredReference=
LYND L R,
VAN ZYL W H,
MCBRIDE J E, et al. Consolidated bioprocessing of cellulosic biomass: an update[J].
Current Opinion in Biotechnology,
2005,
16(5): 577-583., articleTitle=Consolidated bioprocessing of cellulosic biomass: an update, refAbstract=null), Reference(id=1164877083684643470, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2019, volume=285, issue=null, pageStart=121320, pageEnd=null, url=null, language=null, rfNumber=86, rfOrder=91, authorNames=HEO W, KIM J H, KIM S, journalName=Bioresource Technology, refType=null, unstructuredReference=HEO W,
KIM J H,
KIM S, et al. Enhanced production of 3-hydroxypropionic acid from glucose and xylose by alleviation of metabolic congestion due to glycerol flux in engineered
Escherichia coli [J].
Bioresource Technology,
2019,
285: 121320., articleTitle=Enhanced production of 3-hydroxypropionic acid from glucose and xylose by alleviation of metabolic congestion due to glycerol flux in engineered
Escherichia coli, refAbstract=null), Reference(id=1164877083751752338, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=36, issue=6, pageStart=1101, pageEnd=1112, url=null, language=null, rfNumber=87, rfOrder=92, authorNames=詹元龙, 赵瑞英, 崔鸿亮, journalName=生物工程学报, refType=null, unstructuredReference=詹元龙, 赵瑞英, 崔鸿亮, 等. 生物合成3-羟基丙酸的代谢工程研究进展[J].
生物工程学报,
2020,
36(6): 1101-1112., articleTitle=生物合成3-羟基丙酸的代谢工程研究进展, refAbstract=null), Reference(id=1164877083806278293, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=36, issue=6, pageStart=1101, pageEnd=1112, url=null, language=null, rfNumber=87, rfOrder=93, authorNames=ZHAN Y L, ZHAO R Y, CUI H L, journalName=Chinese Journal of Biotechnology, refType=null, unstructuredReference=
ZHAN Y L,
ZHAO R Y,
CUI H L, et al. Progress in metabolic engineering of biosynthesis of 3-hydroxypropionic acid[J].
Chinese Journal of Biotechnology,
2020,
36(6): 1101-1112., articleTitle=null, refAbstract=null), Reference(id=1164877083864998552, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=28, issue=4, pageStart=1888, pageEnd=null, url=null, language=null, rfNumber=88, rfOrder=94, authorNames=WANG X D, CUI Z Z, SUN X, journalName=Molecules, refType=null, unstructuredReference=
WANG X D,
CUI Z Z,
SUN X, et al. Production of 3-hydroxypropionic acid from renewable substrates by metabolically engineered microorganisms: a review[J].
Molecules,
2023,
28(4): 1888., articleTitle=Production of 3-hydroxypropionic acid from renewable substrates by metabolically engineered microorganisms: a review, refAbstract=null), Reference(id=1164877083940496026, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=78, issue=null, pageStart=72, pageEnd=83, url=null, language=null, rfNumber=89, rfOrder=95, authorNames=LIU D, HWANG H J, OTOUPAL P B, journalName=Metabolic Engineering, refType=null, unstructuredReference=
LIU D,
HWANG H J,
OTOUPAL P B, et al. Engineering
Rhodosporidium toruloides for production of 3-hydroxypropionic acid from lignocellulosic hydrolysate[J].
Metabolic Engineering,
2023,
78: 72-83., articleTitle=Engineering
Rhodosporidium toruloides for production of 3-hydroxypropionic acid from lignocellulosic hydrolysate, refAbstract=null), Reference(id=1164877084003410589, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=19, issue=12, pageStart=1524, pageEnd=1531, url=null, language=null, rfNumber=90, rfOrder=96, authorNames=GAO J Q, YU W, LI Y X, journalName=Nature Chemical Biology, refType=null, unstructuredReference=
GAO J Q,
YU W,
LI Y X, et al. Engineering co-utilization of glucose and xylose for chemical overproduction from lignocellulose[J].
Nature Chemical Biology,
2023,
19(12): 1524-1531., articleTitle=Engineering co-utilization of glucose and xylose for chemical overproduction from lignocellulose, refAbstract=null), Reference(id=1164877084070519456, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=16, issue=1, pageStart=53, pageEnd=null, url=null, language=null, rfNumber=91, rfOrder=97, authorNames=DAI Z Y, POMRANING K R, DENG S, journalName=Biotechnology for Biofuels and Bioproducts, refType=null, unstructuredReference=
DAI Z Y,
POMRANING K R,
DENG S, et al. Metabolic engineering to improve production of 3-hydroxypropionic acid from corn-stover hydrolysate in
Aspergillus species[J].
Biotechnology for Biofuels and Bioproducts,
2023,
16(1): 53., articleTitle=Metabolic engineering to improve production of 3-hydroxypropionic acid from corn-stover hydrolysate in
Aspergillus species, refAbstract=null), Reference(id=1164877084133434019, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=39, issue=null, pageStart=151, pageEnd=158, url=null, language=null, rfNumber=92, rfOrder=98, authorNames=CHEN Z, HUANG J H, WU Y, journalName=Metabolic Engineering, refType=null, unstructuredReference=
CHEN Z,
HUANG J H,
WU Y, et al. Metabolic engineering of
Corynebacterium glutamicum for the production of 3-hydroxypropionic acid from glucose and xylose[J].
Metabolic Engineering,
2017,
39: 151-158., articleTitle=Metabolic engineering of
Corynebacterium glutamicum for the production of 3-hydroxypropionic acid from glucose and xylose, refAbstract=null), Reference(id=1164877084200542886, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=37, issue=7, pageStart=117, pageEnd=null, url=null, language=null, rfNumber=93, rfOrder=99, authorNames=ZHAO P, TIAN P F, journalName=World Journal of Microbiology and Biotechnology, refType=null, unstructuredReference=
ZHAO P,
TIAN P F. Biosynthesis pathways and strategies for improving 3-hydroxypropionic acid production in bacteria[J].
World Journal of Microbiology and Biotechnology,
2021,
37(7): 117., articleTitle=Biosynthesis pathways and strategies for improving 3-hydroxypropionic acid production in bacteria, refAbstract=null), Reference(id=1164877084259263145, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=10, issue=9, pageStart=1238, pageEnd=null, url=null, language=null, rfNumber=94, rfOrder=100, authorNames=CHOI S S, LEE H N, PARK E H, journalName=Biomolecules, refType=null, unstructuredReference=
CHOI S S,
LEE H N,
PARK E H, et al. Recent advances in microbial production of
cis,cis-muconic acid[J].
Biomolecules,
2020,
10(9): 1238., articleTitle=Recent advances in microbial production of
cis,cis-muconic acid, refAbstract=null), Reference(id=1164877084334760619, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=20, issue=1, pageStart=114, pageEnd=null, url=null, language=null, rfNumber=95, rfOrder=101, authorNames=NICOLAÏ T, DEPARIS Q, FOULQUIÉ-MORENO M R, journalName=Microbial Cell Factories, refType=null, unstructuredReference=
NICOLAÏ T,
DEPARIS Q,
FOULQUIÉ-MORENO M R, et al.
In-situ muconic acid extraction reveals sugar consumption bottleneck in a xylose-utilizing
Saccharomyces cerevisiae strain[J].
Microbial Cell Factories,
2021,
20(1): 114., articleTitle=
In-situ muconic acid extraction reveals sugar consumption bottleneck in a xylose-utilizing
Saccharomyces cerevisiae strain, refAbstract=null), Reference(id=1164877084389286573, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=75, issue=null, pageStart=153, pageEnd=169, url=null, language=null, rfNumber=96, rfOrder=102, authorNames=WEILAND F, BARTON N, KOHLSTEDT M, journalName=Metabolic Engineering, refType=null, unstructuredReference=
WEILAND F,
BARTON N,
KOHLSTEDT M, et al. Systems metabolic engineering upgrades
Corynebacterium glutamicum to high-efficiency
cis,
cis-muconic acid production from lignin-based aromatics[J].
Metabolic Engineering,
2023,
75: 153-169., articleTitle=Systems metabolic engineering upgrades
Corynebacterium glutamicum to high-efficiency
cis,
cis-muconic acid production from lignin-based aromatics, refAbstract=null), Reference(id=1164877084473172656, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=11, issue=1, pageStart=279, pageEnd=null, url=null, language=null, rfNumber=97, rfOrder=103, authorNames=FUJIWARA R, NODA S, TANAKA T, journalName=Nature Communications, refType=null, unstructuredReference=
FUJIWARA R,
NODA S,
TANAKA T, et al. Metabolic engineering of
Escherichia coli for shikimate pathway derivative production from glucose-xylose co-substrate[J].
Nature Communications,
2020,
11(1): 279., articleTitle=Metabolic engineering of
Escherichia coli for shikimate pathway derivative production from glucose-xylose co-substrate, refAbstract=null), Reference(id=1164877084536087219, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=13, issue=1, pageStart=4925, pageEnd=null, url=null, language=null, rfNumber=98, rfOrder=104, authorNames=LING C, PEABODY G L, SALVACHÚA D, journalName=Nature Communications, refType=null, unstructuredReference=
LING C,
PEABODY G L,
SALVACHÚA D, et al. Muconic acid production from glucose and xylose in
Pseudomonas putida via evolution and metabolic engineering[J].
Nature Communications,
2022,
13(1): 4925., articleTitle=Muconic acid production from glucose and xylose in
Pseudomonas putida via evolution and metabolic engineering, refAbstract=null), Reference(id=1164877084594807478, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=17, issue=1, pageStart=115, pageEnd=null, url=null, language=null, rfNumber=99, rfOrder=105, authorNames=BECKER J, KUHL M, KOHLSTEDT M, journalName=Microbial Cell Factories, refType=null, unstructuredReference=
BECKER J,
KUHL M,
KOHLSTEDT M, et al. Metabolic engineering of
Corynebacterium glutamicum for the production of
cis,
cis-muconic acid from lignin[J].
Microbial Cell Factories,
2018,
17(1): 115., articleTitle=Metabolic engineering of
Corynebacterium glutamicum for the production of
cis,
cis-muconic acid from lignin, refAbstract=null), Reference(id=1164877084653527736, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=47, issue=null, pageStart=279, pageEnd=293, url=null, language=null, rfNumber=100, rfOrder=106, authorNames=KOHLSTEDT M, STARCK S, BARTON N, journalName=Metabolic Engineering, refType=null, unstructuredReference=
KOHLSTEDT M,
STARCK S,
BARTON N, et al. From lignin to nylon: cascaded chemical and biochemical conversion using metabolically engineered
Pseudomonas putida [J].
Metabolic Engineering,
2018,
47: 279-293., articleTitle=From lignin to nylon: cascaded chemical and biochemical conversion using metabolically engineered
Pseudomonas putida, refAbstract=null), Reference(id=1164877084712247995, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=9, issue=3, pageStart=634, pageEnd=646, url=null, language=null, rfNumber=101, rfOrder=107, authorNames=WANG G K, ØZMERIH S, GUERREIRO R, journalName=ACS Synthetic Biology, refType=null, unstructuredReference=
WANG G K,
ØZMERIH S,
GUERREIRO R, et al. Improvement of
cis,
cis-muconic acid production in
Saccharomyces cerevisiae through biosensor-aided genome engineering[J].
ACS Synthetic Biology,
2020,
9(3): 634-646., articleTitle=Improvement of
cis,
cis-muconic acid production in
Saccharomyces cerevisiae through biosensor-aided genome engineering, refAbstract=null), Reference(id=1164877084779356862, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=57, issue=10, pageStart=3545, pageEnd=3553, url=null, language=null, rfNumber=102, rfOrder=108, authorNames=LI X C, ZHANG Y Y, XIA Q N, journalName=Industrial & Engineering Chemistry Research, refType=null, unstructuredReference=
LI X C,
ZHANG Y Y,
XIA Q N, et al. Acid-free conversion of cellulose to 5-(hydroxymethyl)furfural catalyzed by hot seawater[J].
Industrial & Engineering Chemistry Research,
2018,
57(10): 3545-3553., articleTitle=Acid-free conversion of cellulose to 5-(hydroxymethyl)furfural catalyzed by hot seawater, refAbstract=null), Reference(id=1164877084859048641, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=56, issue=6, pageStart=61, pageEnd=70, url=null, language=null, rfNumber=103, rfOrder=109, authorNames=蔡佳伟, 李亢悔, 蒋涌泉, journalName=生物质化学工程, refType=null, unstructuredReference=蔡佳伟, 李亢悔, 蒋涌泉, 等. HMF制备FDCA的新型催化工艺研究进展[J].
生物质化学工程,
2022,
56(6): 61-70., articleTitle=HMF制备FDCA的新型催化工艺研究进展, refAbstract=null), Reference(id=1164877084926157508, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=56, issue=6, pageStart=61, pageEnd=70, url=null, language=null, rfNumber=103, rfOrder=110, authorNames=CAI J W, LI K H, JIANG Y Q, journalName=Biomass Chemical Engineering, refType=null, unstructuredReference=
CAI J W,
LI K H,
JIANG Y Q, et al. Novel catalytic process for preparing FDCA from HMF[J].
Biomass Chemical Engineering,
2022,
56(6): 61-70., articleTitle=null, refAbstract=null), Reference(id=1164877084993266374, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=50, issue=8, pageStart=1939, pageEnd=1943, url=null, language=null, rfNumber=104, rfOrder=111, authorNames=张雷, 孙启梅, 白富栋, journalName=当代化工, refType=null, unstructuredReference=张雷, 孙启梅, 白富栋, 等. 2,5-呋喃二甲酸合成技术路线及应用前景[J].
当代化工,
2021,
50(8): 1939-1943., articleTitle=2,5-呋喃二甲酸合成技术路线及应用前景, refAbstract=null), Reference(id=1164877085056180937, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=50, issue=8, pageStart=1939, pageEnd=1943, url=null, language=null, rfNumber=104, rfOrder=112, authorNames=ZHANG L, SUN Q M, BAI F D, journalName=Contemporary Chemical Industry, refType=null, unstructuredReference=
ZHANG L,
SUN Q M,
BAI F D, et al. Synthetic technical route and application prospects of 2,5-furandicarboxylic acid[J].
Contemporary Chemical Industry,
2021,
50(8): 1939-1943., articleTitle=null, refAbstract=null), Reference(id=1164877085119095499, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=4, issue=9, pageStart=4752, pageEnd=4761, url=null, language=null, rfNumber=105, rfOrder=113, authorNames=WANG Y B, YU K, LEI D, journalName=ACS Sustainable Chemistry & Engineering, refType=null, unstructuredReference=
WANG Y B,
YU K,
LEI D, et al. Basicity-tuned hydrotalcite-supported Pd catalysts for aerobic oxidation of 5-hydroxymethyl-2-furfural under mild conditions[J].
ACS Sustainable Chemistry & Engineering,
2016,
4(9): 4752-4761., articleTitle=Basicity-tuned hydrotalcite-supported Pd catalysts for aerobic oxidation of 5-hydroxymethyl-2-furfural under mild conditions, refAbstract=null), Reference(id=1164877085194592975, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2020, volume=104, issue=2, pageStart=527, pageEnd=543, url=null, language=null, rfNumber=106, rfOrder=114, authorNames=YUAN H B, LIU H L, DU J K, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
YUAN H B,
LIU H L,
DU J K, et al. Biocatalytic production of 2,5-furandicarboxylic acid: recent advances and future perspectives[J].
Applied Microbiology and Biotechnology,
2020,
104(2): 527-543., articleTitle=Biocatalytic production of 2,5-furandicarboxylic acid: recent advances and future perspectives, refAbstract=null), Reference(id=1164877085303644881, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=282, issue=16, pageStart=3218, pageEnd=3229, url=null, language=null, rfNumber=107, rfOrder=115, authorNames=CARRO J, FERREIRA P, RODRÍGUEZ L, journalName=The FEBS Journal, refType=null, unstructuredReference=
CARRO J,
FERREIRA P,
RODRÍGUEZ L, et al. 5-hydroxymethylfurfural conversion by fungal aryl-alcohol oxidase and unspecific peroxygenase[J].
The FEBS Journal,
2015,
282(16): 3218-3229., articleTitle=5-hydroxymethylfurfural conversion by fungal aryl-alcohol oxidase and unspecific peroxygenase, refAbstract=null), Reference(id=1164877085379142354, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=17, issue=6, pageStart=3271, pageEnd=3275, url=null, language=null, rfNumber=108, rfOrder=116, authorNames=MCKENNA S M, LEIMKÜHLER S, HERTER S, journalName=Green Chemistry, refType=null, unstructuredReference=
MCKENNA S M,
LEIMKÜHLER S,
HERTER S, et al. Enzyme cascade reactions: synthesis of furandicarboxylic acid (FDCA) and carboxylic acids using oxidases in tandem[J].
Green Chemistry,
2015,
17(6): 3271-3275., articleTitle=Enzyme cascade reactions: synthesis of furandicarboxylic acid (FDCA) and carboxylic acids using oxidases in tandem, refAbstract=null), Reference(id=1164877085458834132, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2017, volume=19, issue=19, pageStart=4660, pageEnd=4665, url=null, language=null, rfNumber=109, rfOrder=117, authorNames=MCKENNA S M, MINES P, LAW P, journalName=Green Chemistry, refType=null, unstructuredReference=
MCKENNA S M,
MINES P,
LAW P, et al. The continuous oxidation of HMF to FDCA and the immobilisation and stabilisation of periplasmic aldehyde oxidase (PaoABC)[J].
Green Chemistry,
2017,
19(19): 4660-4665., articleTitle=The continuous oxidation of HMF to FDCA and the immobilisation and stabilisation of periplasmic aldehyde oxidase (PaoABC), refAbstract=null), Reference(id=1164877085534331606, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2010, volume=107, issue=11, pageStart=4919, pageEnd=4924, url=null, language=null, rfNumber=110, rfOrder=118, authorNames=KOOPMAN F, WIERCKX N, DE WINDE J H, journalName=Proceedings of the National Academy of Sciences of the United States of America, refType=null, unstructuredReference=
KOOPMAN F,
WIERCKX N,
DE WINDE J H, et al. Identification and characterization of the furfural and 5-(hydroxymethyl)furfural degradation pathways of
Cupriavidus basilensis HMF14[J].
Proceedings of the National Academy of Sciences of the United States of America,
2010,
107(11): 4919-4924., articleTitle=Identification and characterization of the furfural and 5-(hydroxymethyl)furfural degradation pathways of
Cupriavidus basilensis HMF14, refAbstract=null), Reference(id=1164877085601440472, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=53, issue=25, pageStart=6515, pageEnd=6518, url=null, language=null, rfNumber=111, rfOrder=119, authorNames=DIJKMAN W P, GROOTHUIS D E, FRAAIJE M W, journalName=Angewandte Chemie International Edition, refType=null, unstructuredReference=
DIJKMAN W P,
GROOTHUIS D E,
FRAAIJE M W. Enzyme-catalyzed oxidation of 5-hydroxymethylfurfural to furan-2,5-dicarboxylic acid[J].
Angewandte Chemie International Edition,
2014,
53(25): 6515-6518., articleTitle=Enzyme-catalyzed oxidation of 5-hydroxymethylfurfural to furan-2,5-dicarboxylic acid, refAbstract=null), Reference(id=1164877085655966427, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2015, volume=5, issue=3, pageStart=1833, pageEnd=1839, url=null, language=null, rfNumber=112, rfOrder=120, authorNames=DIJKMAN W P, BINDA C, FRAAIJE M W, journalName=ACS Catalysis, refType=null, unstructuredReference=
DIJKMAN W P,
BINDA C,
FRAAIJE M W, et al. Structure-based enzyme tailoring of 5-hydroxymethylfurfural oxidase[J].
ACS Catalysis,
2015,
5(3): 1833-1839., articleTitle=Structure-based enzyme tailoring of 5-hydroxymethylfurfural oxidase, refAbstract=null), Reference(id=1164877085731463901, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2014, volume=98, issue=19, pageStart=8031, pageEnd=8046, url=null, language=null, rfNumber=113, rfOrder=121, authorNames=SCHÜÜRMANN J, QUEHL P, FESTEL G, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
SCHÜÜRMANN J,
QUEHL P,
FESTEL G, et al. Bacterial whole-cell biocatalysts by surface display of enzymes: toward industrial application[J].
Applied Microbiology and Biotechnology,
2014,
98(19): 8031-8046., articleTitle=Bacterial whole-cell biocatalysts by surface display of enzymes: toward industrial application, refAbstract=null), Reference(id=1164877085794378462, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2010, volume=101, issue=16, pageStart=6291, pageEnd=6296, url=null, language=null, rfNumber=114, rfOrder=122, authorNames=KOOPMAN F, WIERCKX N, DE WINDE J H, journalName=Bioresource Technology, refType=null, unstructuredReference=
KOOPMAN F,
WIERCKX N,
DE WINDE J H, et al. Efficient whole-cell biotransformation of 5-(hydroxymethyl)furfural into FDCA, 2,5-furandicarboxylic acid[J].
Bioresource Technology,
2010,
101(16): 6291-6296., articleTitle=Efficient whole-cell biotransformation of 5-(hydroxymethyl)furfural into FDCA, 2,5-furandicarboxylic acid, refAbstract=null), Reference(id=1164877085848904416, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2016, volume=214, issue=null, pageStart=311, pageEnd=318, url=null, language=null, rfNumber=115, rfOrder=123, authorNames=YANG C F, HUANG C R, journalName=Bioresource Technology, refType=null, unstructuredReference=
YANG C F,
HUANG C R. Biotransformation of 5-hydroxy-methylfurfural into 2,5-furan-dicarboxylic acid by bacterial isolate using thermal acid algal hydrolysate[J].
Bioresource Technology,
2016,
214: 311-318., articleTitle=Biotransformation of 5-hydroxy-methylfurfural into 2,5-furan-dicarboxylic acid by bacterial isolate using thermal acid algal hydrolysate, refAbstract=null), Reference(id=1164877085907624675, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=125, issue=4, pageStart=407, pageEnd=412, url=null, language=null, rfNumber=116, rfOrder=124, authorNames=YANG C F, HUANG C R, journalName=Journal of Bioscience and Bioengineering, refType=null, unstructuredReference=
YANG C F,
HUANG C R. Isolation of 5-hydroxymethylfurfural biotransforming bacteria to produce 2,5-furan dicarboxylic acid in algal acid hydrolysate[J].
Journal of Bioscience and Bioengineering,
2018,
125(4): 407-412., articleTitle=Isolation of 5-hydroxymethylfurfural biotransforming bacteria to produce 2,5-furan dicarboxylic acid in algal acid hydrolysate, refAbstract=null), Reference(id=1164877085970539237, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=247, issue=null, pageStart=1184, pageEnd=1188, url=null, language=null, rfNumber=117, rfOrder=125, authorNames=YUAN H B, LI J H, SHIN H D, journalName=Bioresource Technology, refType=null, unstructuredReference=
YUAN H B,
LI J H,
SHIN H D, et al. Improved production of 2,5-furandicarboxylic acid by overexpression of 5-hydroxymethylfurfural oxidase and 5-hydroxymethylfurfural/furfural oxidoreductase in
Raoultella ornithinolytica BF60[J].
Bioresource Technology,
2018,
247: 1184-1188., articleTitle=Improved production of 2,5-furandicarboxylic acid by overexpression of 5-hydroxymethylfurfural oxidase and 5-hydroxymethylfurfural/furfural oxidoreductase in
Raoultella ornithinolytica BF60, refAbstract=null), Reference(id=1164877086046036712, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=115, issue=9, pageStart=2148, pageEnd=2155, url=null, language=null, rfNumber=118, rfOrder=126, authorNames=YUAN H B, LIU Y F, LI J H, journalName=Biotechnology and Bioengineering, refType=null, unstructuredReference=
YUAN H B,
LIU Y F,
LI J H, et al. Combinatorial synthetic pathway fine-tuning and comparative transcriptomics for metabolic engineering of
Raoultella ornithinolytica BF60 to efficiently synthesize 2,5-furandicarboxylic acid[J].
Biotechnology and Bioengineering,
2018,
115(9): 2148-2155., articleTitle=Combinatorial synthetic pathway fine-tuning and comparative transcriptomics for metabolic engineering of
Raoultella ornithinolytica BF60 to efficiently synthesize 2,5-furandicarboxylic acid, refAbstract=null), Reference(id=1164877086129922794, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=28, issue=12, pageStart=1999, pageEnd=2008, url=null, language=null, rfNumber=119, rfOrder=127, authorNames=YUAN H B, LIU Y F, LV X Q, journalName=Journal of Microbiology and Biotechnology, refType=null, unstructuredReference=
YUAN H B,
LIU Y F,
LV X Q, et al. Enhanced 2,5-furandicarboxylic acid (FDCA) production in
Raoultella ornithinolytica BF60 by manipulation of the key genes in FDCA biosynthesis pathway[J].
Journal of Microbiology and Biotechnology,
2018,
28(12): 1999-2008., articleTitle=Enhanced 2,5-furandicarboxylic acid (FDCA) production in
Raoultella ornithinolytica BF60 by manipulation of the key genes in FDCA biosynthesis pathway, refAbstract=null), Reference(id=1164877086192837355, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2008, volume=40, issue=1, pageStart=68, pageEnd=75, url=null, language=null, rfNumber=120, rfOrder=128, authorNames=MICHINOBU T, HISHIDA M, SATO M, journalName=Polymer Journal, refType=null, unstructuredReference=
MICHINOBU T,
HISHIDA M,
SATO M, et al. Polyesters of 2-pyrone-4,6-dicarboxylic acid (PDC) obtained from a metabolic intermediate of lignin[J].
Polymer Journal,
2008,
40(1): 68-75., articleTitle=Polyesters of 2-pyrone-4,6-dicarboxylic acid (PDC) obtained from a metabolic intermediate of lignin, refAbstract=null), Reference(id=1164877086247363310, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2006, volume=71, issue=5, pageStart=608, pageEnd=614, url=null, language=null, rfNumber=121, rfOrder=129, authorNames=OTSUKA Y, NAKAMURA M, SHIGEHARA K, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
OTSUKA Y,
NAKAMURA M,
SHIGEHARA K, et al. Efficient production of 2-pyrone 4,6-dicarboxylic acid as a novel polymer-based material from protocatechuate by microbial function[J].
Applied Microbiology and Biotechnology,
2006,
71(5): 608-614., articleTitle=Efficient production of 2-pyrone 4,6-dicarboxylic acid as a novel polymer-based material from protocatechuate by microbial function, refAbstract=null), Reference(id=1164877086301889265, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2010, volume=47, issue=6, pageStart=564, pageEnd=570, url=null, language=null, rfNumber=122, rfOrder=130, authorNames=MICHINOBU T, BITO M, TANIMURA M, journalName=Journal of Macromolecular Science, Part A, refType=null, unstructuredReference=
MICHINOBU T,
BITO M,
TANIMURA M, et al. Synthesis and characterization of hybrid biopolymers of L-lactic acid and 2-pyrone-4,6-dicarboxylic acid[J].
Journal of Macromolecular Science, Part A,
2010,
47(6): 564-570., articleTitle=Synthesis and characterization of hybrid biopolymers of L-lactic acid and 2-pyrone-4,6-dicarboxylic acid, refAbstract=null), Reference(id=1164877086356415220, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=7, issue=9, pageStart=2296, pageEnd=2307, url=null, language=null, rfNumber=123, rfOrder=131, authorNames=LUO Z W, KIM W J, LEE S Y, journalName=ACS Synthetic Biology, refType=null, unstructuredReference=
LUO Z W,
KIM W J,
LEE S Y. Metabolic engineering of
Escherichia coli for efficient production of 2-pyrone-4,6-dicarboxylic acid from glucose[J].
ACS Synthetic Biology,
2018,
7(9): 2296-2307., articleTitle=Metabolic engineering of
Escherichia coli for efficient production of 2-pyrone-4,6-dicarboxylic acid from glucose, refAbstract=null), Reference(id=1164877086415135479, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=16, issue=1, pageStart=92, pageEnd=null, url=null, language=null, rfNumber=124, rfOrder=132, authorNames=ZHOU D, WU F L, PENG Y F, journalName=Biotechnology for Biofuels and Bioproducts, refType=null, unstructuredReference=
ZHOU D,
WU F L,
PENG Y F, et al. Multi-step biosynthesis of the biodegradable polyester monomer 2-pyrone-4,6-dicarboxylic acid from glucose[J].
Biotechnology for Biofuels and Bioproducts,
2023,
16(1): 92., articleTitle=Multi-step biosynthesis of the biodegradable polyester monomer 2-pyrone-4,6-dicarboxylic acid from glucose, refAbstract=null), Reference(id=1164877086519993082, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=352, issue=null, pageStart=127106, pageEnd=null, url=null, language=null, rfNumber=125, rfOrder=133, authorNames=LEE S S, JUNG Y J, PARK S J, journalName=Bioresource Technology, refType=null, unstructuredReference=
LEE S S,
JUNG Y J,
PARK S J, et al. Microbial production of 2-pyrone-4,6-dicarboxylic acid from lignin derivatives in an engineered
Pseudomonas putida and its application for the synthesis of bio-based polyester[J].
Bioresource Technology,
2022,
352: 127106., articleTitle=Microbial production of 2-pyrone-4,6-dicarboxylic acid from lignin derivatives in an engineered
Pseudomonas putida and its application for the synthesis of bio-based polyester, refAbstract=null), Reference(id=1164877086582907645, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2023, volume=377, issue=null, pageStart=128956, pageEnd=null, url=null, language=null, rfNumber=126, rfOrder=134, authorNames=OTSUKA Y, ARAKI T, SUZUKI Y, journalName=Bioresource Technology, refType=null, unstructuredReference=
OTSUKA Y,
ARAKI T,
SUZUKI Y, et al. High-level production of 2-pyrone-4,6-dicarboxylic acid from vanillic acid as a lignin-related aromatic compound by metabolically engineered fermentation to realize industrial valorization processes of lignin[J].
Bioresource Technology,
2023,
377: 128956., articleTitle=High-level production of 2-pyrone-4,6-dicarboxylic acid from vanillic acid as a lignin-related aromatic compound by metabolically engineered fermentation to realize industrial valorization processes of lignin, refAbstract=null), Reference(id=1164877086670988032, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2021, volume=65, issue=null, pageStart=111, pageEnd=122, url=null, language=null, rfNumber=127, rfOrder=135, authorNames=NOTONIER S, WERNER A Z, KUATSJAH E, journalName=Metabolic Engineering, refType=null, unstructuredReference=
NOTONIER S,
WERNER A Z,
KUATSJAH E, et al. Metabolism of syringyl lignin-derived compounds in
Pseudomonas putida enables convergent production of 2-pyrone-4,6-dicarboxylic acid[J].
Metabolic Engineering,
2021,
65: 111-122., articleTitle=Metabolism of syringyl lignin-derived compounds in
Pseudomonas putida enables convergent production of 2-pyrone-4,6-dicarboxylic acid, refAbstract=null), Reference(id=1164877086746485507, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2018, volume=102, issue=11, pageStart=4807, pageEnd=4816, url=null, language=null, rfNumber=128, rfOrder=136, authorNames=MORI K, KAMIMURA N, MASAI E, journalName=Applied Microbiology and Biotechnology, refType=null, unstructuredReference=
MORI K,
KAMIMURA N,
MASAI E. Identification of the protocatechuate transporter gene in
Sphingobium sp. strain SYK-6 and effects of overexpression on production of a value-added metabolite[J].
Applied Microbiology and Biotechnology,
2018,
102(11): 4807-4816., articleTitle=Identification of the protocatechuate transporter gene in
Sphingobium sp. strain SYK-6 and effects of overexpression on production of a value-added metabolite, refAbstract=null), Reference(id=1164877086809400069, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=40, issue=2, pageStart=6, pageEnd=11, url=null, language=null, rfNumber=129, rfOrder=137, authorNames=魏珣, 林长喜, journalName=化学工业, refType=null, unstructuredReference=魏珣, 林长喜. 我国生物基材料产业发展对策与建议[J].
化学工业,
2022,
40(2): 6-11, 23., articleTitle=我国生物基材料产业发展对策与建议, refAbstract=null), Reference(id=1164877086880703239, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, doi=null, pmid=null, pmcid=null, year=2022, volume=40, issue=2, pageStart=6, pageEnd=11, url=null, language=null, rfNumber=129, rfOrder=138, authorNames=WEI X, LIN C X, journalName=Chemical Industry, refType=null, unstructuredReference=
WEI X,
LIN C X. The development strategies and suggestions of domestic bio-based materials industry[J].
Chemical Industry,
2022,
40(2): 6-11, 23., articleTitle=null, refAbstract=null)], funds=[Fund(id=1164877077724537351, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, awardId=2024YFC3407100, language=CN, fundingSource=国家重点研发计划(2024YFC3407100), fundOrder=null, country=null)], companyList=[AuthorCompany(id=1164877074754970060, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=1, ext=[AuthorCompanyExt(id=1164877074763358669, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 State Key Laboratory of Bioreactor Engineering,East China University of Science and Technology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074771747278, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074754970060, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
1 华东理工大学生物反应器工程国家重点实验室,上海 200237)]), AuthorCompany(id=1164877074851439055, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=2, ext=[AuthorCompanyExt(id=1164877074859827664, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 Luhua Institute of Biotechnology,Shanghai 200237,China), AuthorCompanyExt(id=1164877074864021969, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074851439055, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
2 鲁华生物技术研究所,上海 200237)]), AuthorCompany(id=1164877074931130834, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, xref=3, ext=[AuthorCompanyExt(id=1164877074939519443, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=EN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 Key Laboratory of Biocatalysis and Intelligent Manufacturing of China Light Industry,Shanghai 200237,China), AuthorCompanyExt(id=1164877074947908052, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, companyId=1164877074931130834, language=CN, country=null, province=null, city=null, postcode=null, companyName=null, departmentName=null, remark=
3 中国轻工业生物催化与智能制造重点实验室,上海 200237)])], figs=[ArticleFig(id=1164877076487217651, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Fig. 1, caption=
Green biomanufacturing process based on lignocellulose, figureFileSmall=DEEanLYy1Zvf4qpUWszj8Q==, figureFileBig=A1AWrPOO9dMfdSkxB9m1pw==, tableContent=null), ArticleFig(id=1164877076545937908, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=图1, caption=
基于木质纤维素的绿色生物制造流程, figureFileSmall=DEEanLYy1Zvf4qpUWszj8Q==, figureFileBig=A1AWrPOO9dMfdSkxB9m1pw==, tableContent=null), ArticleFig(id=1164877076604658165, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Fig. 2, caption=
Three common pathways for 3-hydroxypropionic acid (3-HP) synthesis in microorganisms PduP—Propionaldehyde dehydrogenase; PduL—Phosphotransferase; PduW—propionic acid kinase; XylA—Xylose isomerase; XylB—Xylulokinase; ASPA—Aspartate ammonia-lyase; PDH—Pyruvate dehydrogenase; BAPAT—β-Alanine pyruvate transaminase; ACC—Acetyl-CoA carboxylase; PAND—Aspartate-α-decarboxylase; MCR—NADPH-dependent malonyl-CoA reductase
, figureFileSmall=sO0bDLEs5juKGW/DEtrWIg==, figureFileBig=XkofyBEx9XYoyfi5Dhtctw==, tableContent=null), ArticleFig(id=1164877076650795510, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=图2, caption=
微生物合成3-羟基丙酸(3-HP)的三条常见途径 PduP—丙醛脱氢酶;PduL—磷酸转乙酰化酶;PduW—丙酸激酶;XylA—木糖异构酶;XylB—木酮糖激酶;ASPA—天冬氨酸氨水解酶;PDH—丙酮酸脱氢酶;BAPAT—β-丙氨酸丙酮酸转氨酶;ACC—乙酰-CoA 羧化酶;PAND—天冬氨酸-α-脱羧酶;MCR—NADPH依赖型丙二酰辅酶A还原酶
, figureFileSmall=sO0bDLEs5juKGW/DEtrWIg==, figureFileBig=XkofyBEx9XYoyfi5Dhtctw==, tableContent=null), ArticleFig(id=1164877076701127159, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Fig. 3, caption=
Enzymatic methods for synthesis of 2,5-furandicarboxylic acid (FDCA) from 5-hydroxymethylfurfural, figureFileSmall=EBwOiPXbpGjh+Sa0lv4fOg==, figureFileBig=T9HhA0gTv5kCgnS1EHhnSA==, tableContent=null), ArticleFig(id=1164877076751458808, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=图3, caption=
5-羟甲基糠醛合成2,5-呋喃二甲酸(FDCA)的酶催化方法, figureFileSmall=EBwOiPXbpGjh+Sa0lv4fOg==, figureFileBig=T9HhA0gTv5kCgnS1EHhnSA==, tableContent=null), ArticleFig(id=1164877076797596153, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Fig. 4, caption=
Synthetic pathway of 2-pyrone-4, 6-dicarboxylic acid (PDC) G—guaiacyl monomer; S—syringyl monomer; H—p-hydroxyphenyl monomer; LigAB—PCA 4,5-dioxygenase; LigC—4-carboxy-2-hydroxymuconate-6-semialdehyde dehydrogenase
, figureFileSmall=LR+Yhnl94QydaScn8pnmag==, figureFileBig=ufD3RPiWz90mOg27esYKGw==, tableContent=null), ArticleFig(id=1164877076847927802, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=图4, caption=
2-吡喃酮-4,6-二羧酸(PDC)的合成途径 G—愈创木基结构单元;S—紫丁香基结构单元;H—对羟基苯基结构单元;LigAB—原儿茶酸4,5-双加氧酶;LigC—4-羧基-2-羟基木酸酯-6-半醛脱氢酶
, figureFileSmall=LR+Yhnl94QydaScn8pnmag==, figureFileBig=ufD3RPiWz90mOg27esYKGw==, tableContent=null), ArticleFig(id=1164877076902453755, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 1, caption=
Common pretreatment processes of lignocellulose together with their advantages and disadvantages
, figureFileSmall=null, figureFileBig=null, tableContent=
| 预处理类型 | 预处理技术 | 优点 | 缺点 | 参考文献 |
| 物理法 | 机械预处理 | 没有抑制物的产生且操作简单 | 设备昂贵且耗能高 | [20] |
| 超声波预处理 | 处理效率高且无抑制剂产生 | 能耗较高且选择性较低 | [22-23] |
| 微波预处理 | 反应迅速且选择性较高 | 设备昂贵且运行成本较高 | [24-25] |
| 射线预处理 | 工艺方便、环保且经济 | 需要结合额外的物理或化学法预处理 | [26-27] |
| 脉冲电场预处理 | 反应快速且节能,需要简单的非热设备 | 需要多个脉冲发生器,且可能产生有毒化学物质 | [28-29] |
| 超临界CO2爆破 | 所需处理温度较低且廉价的CO2 | 需要较高的CO2压力,设备成本较高 | [30] |
| 等离子体预处理 | 过程中不产生有毒或污染化学物 | 能耗较高 | [31] |
| 化学法 | 酸处理 | 对糖的转化率较高,反应时间短 | 强酸毒性较大、腐蚀性强且处理过程会产生抑制物 | [32] |
| 碱处理 | 工艺简单且条件温和,抑制物产生相对较少 | 下游回收过程复杂 | [33-34] |
| 氧化剂预处理 | 选择性高 | 容易导致抑制物的产生 | [35-36] |
| 离子溶液预处理 | 可回收重复使用,且热稳定性较好 | 成本较高且再生条件较高 | [18,37] |
| 有机溶剂预处理 | 反应时间短 | 部分有机溶剂的腐蚀性和毒性较大,且具有易燃性和挥发性 | [38] |
| 深共晶溶剂预处理 | 成本和毒性较高 | 黏稠度较高 | [39-40] |
| 生物法 | 真菌预处理 | 反应温和且能耗低 | 反应周期较长,回收率需要进一步提高 | [41] |
| 细菌预处理 | 反应温和且能耗低 | 反应周期较长 | [42] |
| 白蚁预处理 | 反应温和且能耗低 | 反应周期较长 | [43] |
| 物理-化学共处理 | 蒸气爆破处理 | 处理方式环保 | 能耗较高,对软木的处理效果较差 | [44] |
| 热碱处理 | 处理成本低 | 需要较高的温度和压力 | [45] |
| 氨纤维爆破预处理 | 条件温和且无抑制产生 | 反应能耗较高,且污染环境 | [46] |
| 化学-生物共处理 | 铜绿假单胞菌与稀酸共处理 | 处理效率提高 | 需要进一步优化细菌的处理条件 | [47] |
| 鞘氨醇杆菌与NaOH共处理 | 提高了纤维素水解物的得率 | 需要进一步优化条件 | [48] |
), ArticleFig(id=1164877076969562620, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表1, caption=
木质纤维素常见的预处理工艺及其优缺点
, figureFileSmall=null, figureFileBig=null, tableContent=
| 预处理类型 | 预处理技术 | 优点 | 缺点 | 参考文献 |
| 物理法 | 机械预处理 | 没有抑制物的产生且操作简单 | 设备昂贵且耗能高 | [20] |
| 超声波预处理 | 处理效率高且无抑制剂产生 | 能耗较高且选择性较低 | [22-23] |
| 微波预处理 | 反应迅速且选择性较高 | 设备昂贵且运行成本较高 | [24-25] |
| 射线预处理 | 工艺方便、环保且经济 | 需要结合额外的物理或化学法预处理 | [26-27] |
| 脉冲电场预处理 | 反应快速且节能,需要简单的非热设备 | 需要多个脉冲发生器,且可能产生有毒化学物质 | [28-29] |
| 超临界CO2爆破 | 所需处理温度较低且廉价的CO2 | 需要较高的CO2压力,设备成本较高 | [30] |
| 等离子体预处理 | 过程中不产生有毒或污染化学物 | 能耗较高 | [31] |
| 化学法 | 酸处理 | 对糖的转化率较高,反应时间短 | 强酸毒性较大、腐蚀性强且处理过程会产生抑制物 | [32] |
| 碱处理 | 工艺简单且条件温和,抑制物产生相对较少 | 下游回收过程复杂 | [33-34] |
| 氧化剂预处理 | 选择性高 | 容易导致抑制物的产生 | [35-36] |
| 离子溶液预处理 | 可回收重复使用,且热稳定性较好 | 成本较高且再生条件较高 | [18,37] |
| 有机溶剂预处理 | 反应时间短 | 部分有机溶剂的腐蚀性和毒性较大,且具有易燃性和挥发性 | [38] |
| 深共晶溶剂预处理 | 成本和毒性较高 | 黏稠度较高 | [39-40] |
| 生物法 | 真菌预处理 | 反应温和且能耗低 | 反应周期较长,回收率需要进一步提高 | [41] |
| 细菌预处理 | 反应温和且能耗低 | 反应周期较长 | [42] |
| 白蚁预处理 | 反应温和且能耗低 | 反应周期较长 | [43] |
| 物理-化学共处理 | 蒸气爆破处理 | 处理方式环保 | 能耗较高,对软木的处理效果较差 | [44] |
| 热碱处理 | 处理成本低 | 需要较高的温度和压力 | [45] |
| 氨纤维爆破预处理 | 条件温和且无抑制产生 | 反应能耗较高,且污染环境 | [46] |
| 化学-生物共处理 | 铜绿假单胞菌与稀酸共处理 | 处理效率提高 | 需要进一步优化细菌的处理条件 | [47] |
| 鞘氨醇杆菌与NaOH共处理 | 提高了纤维素水解物的得率 | 需要进一步优化条件 | [48] |
), ArticleFig(id=1164877077036671485, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 2, caption=
Primary detoxification methods and their applicable scopes
, figureFileSmall=null, figureFileBig=null, tableContent=
| 脱毒分类 | 脱毒方法 | 适用范围 | 参考文献 |
| 物理脱毒 | 吸附剂脱毒 | 呋喃、脂肪酸和酚类物质 | [50] |
| 膜脱毒法 | 酸法预处理抑制物 | [51] |
| 化学脱毒 | 碱法脱毒 | 酸类与呋喃类 | [52] |
| 还原剂脱毒 | 呋喃类与酚类 | [53] |
| 氨基酸脱毒 | 呋喃类与醛类 | [54] |
| 生物脱毒 | 酶法脱毒 | 酚类 | [55] |
| 高耐受抑制物的菌株 | 糠醛类与呋喃类 | [56] |
| 复合脱毒方法 | 离子交换树脂与活性炭 | 酚类与呋喃类 | [57] |
), ArticleFig(id=1164877077107974654, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表2, caption=
主要脱毒方法及其适用范围
, figureFileSmall=null, figureFileBig=null, tableContent=
| 脱毒分类 | 脱毒方法 | 适用范围 | 参考文献 |
| 物理脱毒 | 吸附剂脱毒 | 呋喃、脂肪酸和酚类物质 | [50] |
| 膜脱毒法 | 酸法预处理抑制物 | [51] |
| 化学脱毒 | 碱法脱毒 | 酸类与呋喃类 | [52] |
| 还原剂脱毒 | 呋喃类与酚类 | [53] |
| 氨基酸脱毒 | 呋喃类与醛类 | [54] |
| 生物脱毒 | 酶法脱毒 | 酚类 | [55] |
| 高耐受抑制物的菌株 | 糠醛类与呋喃类 | [56] |
| 复合脱毒方法 | 离子交换树脂与活性炭 | 酚类与呋喃类 | [57] |
), ArticleFig(id=1164877077166694911, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 3, caption=
Research progress in the bio-synthesis of succinic acid (SA) from lignocellulosic biomass
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 产率 | 生产强度 | 参考文献 |
| E. coli NZN111 | 木薯淀粉和生木薯 | 敲除pflB、ldhA | 优化发酵温度以及底物添加量等条件 | 好氧-厌氧两阶段发酵 | 127.1 g/L | — | — | [71-72] |
| E. coli AFP111 | 葡萄糖 | 在ptsG突变的菌株中敲除pflB和ldhA | 控制葡萄糖的补加量以及菌体生长速度 | 好氧-厌氧两阶段发酵 | 99.2 g/L | 110%(摩尔转化率) | 1.30 g/(L·h) | [73] |
| E. coli SD121 | 葡萄糖 | 过表达ppc,敲除pflB、ldhA和ptsG | 控制溶氧以及生物量 | 好氧-厌氧两阶段发酵 | 116.2 g/L | 1.73 mol/mol | 1.55 g/(L·h) | [74] |
| E. coli AFP111/pTrcC-cscA | 蔗糖和糖蜜 | 在E. coli AFP111的基础上,融合表达CscA与OmpC的锚定基序 | 控制pH以及底物添加量 | 好氧-厌氧两阶段发酵 | 79.0 g/L | 1.20 mol/mol | 1.05 g/(L·h) | [75] |
| C. glutamicum S071/pGEX4-NCgl0275 | 葡萄糖 | 过表达Ncgl0275、pyc P458S、pck、ppc、fdh和gapA | 优化葡萄糖的补加量以及生物量 | 好氧-厌氧两阶段发酵 | 152.2 g/L | 1.67 mol/mol | 1.11 g/(L·h) | [76] |
| C. glutamicum ΔldhA-pCRA717 | 葡萄糖 | 过表达pyc,敲除ldhA | 优化碳酸氢盐浓度,溶氧以及pH | 好氧-厌氧两阶段发酵 | 146.0 g/L | 1.40 mol/mol | 3.2 g/(L·h) | [77] |
| S. cerevisiae PMCFfg | 葡萄糖 | 敲除fum1、gpd1、pdc1、pdc5和pdc6,过表达pyc2、mdh3、fumC和frds1 | 控制尿素、碳酸钙和生物素的浓度 | 好氧发酵 | 12.9 g/L | 0.21 mol/mol | — | [78] |
| Y. lipolytica Hi-SA2 | 葡萄糖 | 合理分配亚细胞区室还原性TCA循环的代谢流 | 控制葡萄糖添加量 | 好氧发酵 | 111.9 g/L | 0.79 g/g | 1.79 g/(L·h) | [79] |
| A. succinogenes 130Z-pMDH | 葡萄糖和木糖 | 过表达mdh | 优化温度以及pH | 厌氧发酵 | 34.2 g/L | 0.71 g/g | 0.36 g/(L·h) | [80] |
| Y. lipolytica PGC01003 | 甘油 | 敲除Ylsdh5 | 优化pH、通气量以及底物添加量 | 好氧发酵 | 160.2 g/L | 0.40 g/g | 0.40 g/(L·h) | [81] |
| A. succinogenes CGMCC1593 | 玉米秸秆 | — | 优化稀碱预处理、底物浓度、酶负荷和发酵温度 | 同步糖化和发酵(SSF) | 47.4 g/L | 0.72 g/g | 0.99 g/(L·h) | [82] |
| E. coli XW136 | 半纤维素水解液 | 以E.coli KJ122为出发菌株在木糖AM1培养基中连续传代,得到SA滴度提高5倍的突变体,敲除yqhD引入ackA::PyadC fucO-ucpA adhE::fucO | 优化半纤维素水解液的制备,以及发酵过程pH的控制 | 分批发酵 | 32.0 g/L | 0.90 g/g | — | [83] |
| T. thermosaccharolyticum M5和A. succinogenes 130Z | 木聚糖 | — | 优化底物浓度、pH、MgCO3浓度以及接种时间 | 联合生物处理(CBP) | 32.5 g/L | 0.39 g/g | — | [84] |
), ArticleFig(id=1164877077250580992, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表3, caption=
利用木质纤维素生物质为原料生物合成丁二酸(SA)的研究进展
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 产率 | 生产强度 | 参考文献 |
| E. coli NZN111 | 木薯淀粉和生木薯 | 敲除pflB、ldhA | 优化发酵温度以及底物添加量等条件 | 好氧-厌氧两阶段发酵 | 127.1 g/L | — | — | [71-72] |
| E. coli AFP111 | 葡萄糖 | 在ptsG突变的菌株中敲除pflB和ldhA | 控制葡萄糖的补加量以及菌体生长速度 | 好氧-厌氧两阶段发酵 | 99.2 g/L | 110%(摩尔转化率) | 1.30 g/(L·h) | [73] |
| E. coli SD121 | 葡萄糖 | 过表达ppc,敲除pflB、ldhA和ptsG | 控制溶氧以及生物量 | 好氧-厌氧两阶段发酵 | 116.2 g/L | 1.73 mol/mol | 1.55 g/(L·h) | [74] |
| E. coli AFP111/pTrcC-cscA | 蔗糖和糖蜜 | 在E. coli AFP111的基础上,融合表达CscA与OmpC的锚定基序 | 控制pH以及底物添加量 | 好氧-厌氧两阶段发酵 | 79.0 g/L | 1.20 mol/mol | 1.05 g/(L·h) | [75] |
| C. glutamicum S071/pGEX4-NCgl0275 | 葡萄糖 | 过表达Ncgl0275、pyc P458S、pck、ppc、fdh和gapA | 优化葡萄糖的补加量以及生物量 | 好氧-厌氧两阶段发酵 | 152.2 g/L | 1.67 mol/mol | 1.11 g/(L·h) | [76] |
| C. glutamicum ΔldhA-pCRA717 | 葡萄糖 | 过表达pyc,敲除ldhA | 优化碳酸氢盐浓度,溶氧以及pH | 好氧-厌氧两阶段发酵 | 146.0 g/L | 1.40 mol/mol | 3.2 g/(L·h) | [77] |
| S. cerevisiae PMCFfg | 葡萄糖 | 敲除fum1、gpd1、pdc1、pdc5和pdc6,过表达pyc2、mdh3、fumC和frds1 | 控制尿素、碳酸钙和生物素的浓度 | 好氧发酵 | 12.9 g/L | 0.21 mol/mol | — | [78] |
| Y. lipolytica Hi-SA2 | 葡萄糖 | 合理分配亚细胞区室还原性TCA循环的代谢流 | 控制葡萄糖添加量 | 好氧发酵 | 111.9 g/L | 0.79 g/g | 1.79 g/(L·h) | [79] |
| A. succinogenes 130Z-pMDH | 葡萄糖和木糖 | 过表达mdh | 优化温度以及pH | 厌氧发酵 | 34.2 g/L | 0.71 g/g | 0.36 g/(L·h) | [80] |
| Y. lipolytica PGC01003 | 甘油 | 敲除Ylsdh5 | 优化pH、通气量以及底物添加量 | 好氧发酵 | 160.2 g/L | 0.40 g/g | 0.40 g/(L·h) | [81] |
| A. succinogenes CGMCC1593 | 玉米秸秆 | — | 优化稀碱预处理、底物浓度、酶负荷和发酵温度 | 同步糖化和发酵(SSF) | 47.4 g/L | 0.72 g/g | 0.99 g/(L·h) | [82] |
| E. coli XW136 | 半纤维素水解液 | 以E.coli KJ122为出发菌株在木糖AM1培养基中连续传代,得到SA滴度提高5倍的突变体,敲除yqhD引入ackA::PyadC fucO-ucpA adhE::fucO | 优化半纤维素水解液的制备,以及发酵过程pH的控制 | 分批发酵 | 32.0 g/L | 0.90 g/g | — | [83] |
| T. thermosaccharolyticum M5和A. succinogenes 130Z | 木聚糖 | — | 优化底物浓度、pH、MgCO3浓度以及接种时间 | 联合生物处理(CBP) | 32.5 g/L | 0.39 g/g | — | [84] |
), ArticleFig(id=1164877077317689857, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 4, caption=
Research progress in the bio-synthesis of 3-hydroxypropionic acid (3-HP) from lignocellulosic biomass
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| R. toruloides MCR-ALD6-g2945 | 葡萄糖和木糖 | 外源表达A. pseudoterreus来源的羧酸转运体 | 优化培养基的碳氮比 | 补料分批发酵 | 45.4 g/L | 0.11 g/g | 0.44 g/(L·h) | [89] |
| O. polymorpha XFML | 葡萄糖和木糖 | 优化葡萄糖和木糖共利用系统以及重塑中枢代谢途径 | 控制补糖速度 | 补料分批发酵 | 79.6 g/L | 0.35 g/g① | 0.41 g/(L·h)① | [90] |
| A. niger An3HP9/pyc2/ald6a∆/3HP-6 | 玉米秸秆水解物 | 优化3-HP代谢途径关键基因的表达,提高前体供应水平以及强化外排转运蛋白 | 优化发酵温度以及培养基成分 | 分批发酵 | 36.0 g/L | 0.48 g/g | 0.21 g/(L·h) | [91] |
| C. glutamicum MH15 | 葡萄糖和木糖 | 构建甘油利用途径,并微室化定位甘油合成途径,弱化乳酸和乙酸等副产物合成以及构建糖转运利用系统 | 控制补糖速度和底物浓度 | 补料分批发酵 | 62.6 g/L | 0.51 g/g | — | [92] |
), ArticleFig(id=1164877077380604418, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表4, caption=
利用木质纤维素生物质为原料生物合成3-羟基丙酸(3-HP)的研究进展
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| R. toruloides MCR-ALD6-g2945 | 葡萄糖和木糖 | 外源表达A. pseudoterreus来源的羧酸转运体 | 优化培养基的碳氮比 | 补料分批发酵 | 45.4 g/L | 0.11 g/g | 0.44 g/(L·h) | [89] |
| O. polymorpha XFML | 葡萄糖和木糖 | 优化葡萄糖和木糖共利用系统以及重塑中枢代谢途径 | 控制补糖速度 | 补料分批发酵 | 79.6 g/L | 0.35 g/g① | 0.41 g/(L·h)① | [90] |
| A. niger An3HP9/pyc2/ald6a∆/3HP-6 | 玉米秸秆水解物 | 优化3-HP代谢途径关键基因的表达,提高前体供应水平以及强化外排转运蛋白 | 优化发酵温度以及培养基成分 | 分批发酵 | 36.0 g/L | 0.48 g/g | 0.21 g/(L·h) | [91] |
| C. glutamicum MH15 | 葡萄糖和木糖 | 构建甘油利用途径,并微室化定位甘油合成途径,弱化乳酸和乙酸等副产物合成以及构建糖转运利用系统 | 控制补糖速度和底物浓度 | 补料分批发酵 | 62.6 g/L | 0.51 g/g | — | [92] |
), ArticleFig(id=1164877077435130371, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 5, caption=
Research progress in the bio-synthesis of cis,cis-muconic acid (MA) from lignocellulosic biomass
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| E.coli GX2xMA | 葡萄糖和木糖 | 引入木糖代谢途径并优化葡萄糖利用途径 | 优化底物浓度 | 分批发酵 | 4.09 g/L | 0.31 g/g | — | [97] |
| P. putida LC224 | 葡萄糖和木糖 | 敲除hexR并优化木糖异构酶途径,结合代谢模型和适应性进化工程策略 | 控制补糖速度以及溶氧 | 补料分批发酵 | 33.7 g/L | 46%(摩尔转化率) | 0.18 g/(L·h) | [98] |
| S. cerevisiae TN22 | 葡萄糖和木糖 | 解除芳香氨基酸对莽草酸合成途径的反馈抑制,消除乙醇积累和优化辅因子供给 | 添加聚丙烯乙二醇4000提取MA | 补料分批发酵 | 4.5 g/L | — | — | [95] |
| C. glutamicum MA-2 | 葡萄糖和儿茶酚 | 敲除MA环异构酶(CatB)并过表达儿茶酚1,2-二氧酶(CatA) | 控制补料速度和溶氧 | 补料分批发酵 | 85.0 g/L | — | 1.42 g/(L·h)① | [99] |
| P. putida MA-1 | 葡萄糖和儿茶酚 | 敲除catBC | 控制溶氧和pH,用氮气对儿茶酚进行脱气以防止其氧化 | 补料分批发酵 | 64.2 g/L | — | 4.50 g/(L·h) | [100] |
), ArticleFig(id=1164877077489656324, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表5, caption=
利用木质纤维素生物质为原料生物合成黏康酸(MA)的研究进展
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| E.coli GX2xMA | 葡萄糖和木糖 | 引入木糖代谢途径并优化葡萄糖利用途径 | 优化底物浓度 | 分批发酵 | 4.09 g/L | 0.31 g/g | — | [97] |
| P. putida LC224 | 葡萄糖和木糖 | 敲除hexR并优化木糖异构酶途径,结合代谢模型和适应性进化工程策略 | 控制补糖速度以及溶氧 | 补料分批发酵 | 33.7 g/L | 46%(摩尔转化率) | 0.18 g/(L·h) | [98] |
| S. cerevisiae TN22 | 葡萄糖和木糖 | 解除芳香氨基酸对莽草酸合成途径的反馈抑制,消除乙醇积累和优化辅因子供给 | 添加聚丙烯乙二醇4000提取MA | 补料分批发酵 | 4.5 g/L | — | — | [95] |
| C. glutamicum MA-2 | 葡萄糖和儿茶酚 | 敲除MA环异构酶(CatB)并过表达儿茶酚1,2-二氧酶(CatA) | 控制补料速度和溶氧 | 补料分批发酵 | 85.0 g/L | — | 1.42 g/(L·h)① | [99] |
| P. putida MA-1 | 葡萄糖和儿茶酚 | 敲除catBC | 控制溶氧和pH,用氮气对儿茶酚进行脱气以防止其氧化 | 补料分批发酵 | 64.2 g/L | — | 4.50 g/(L·h) | [100] |
), ArticleFig(id=1164877077556765189, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=EN, label=Table 6, caption=
Research progress of bio-synthesis of 2-pyrone-4,6-dicarboxylic acid (PDC)
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| E.coli GYT7 | 葡萄糖 | 过表达抗反馈抑制的3-脱氧-D-阿拉伯庚酮糖-7-磷酸合成酶,提高前体和优化辅因子的供应水平,并结合计算机模拟分析代谢流 | 偶联pH进行补料 | 补料分批发酵 | 16.7 g/L | 0.20 g/g | 0.17 g/(L·h) | [123] |
| E. coli WJ060、E. coli BL21(DE3)-pET30a-AbquiC和E. coli BL21(DE3)-pRSF-2ABC | 葡萄糖 | 模块化工程,利用葡萄糖合成DHS,接着合成为PCA,最后被催化为PDC | 优化全细胞催化的pH以及负载量等条件 | 补料分批发酵 | 49.2 g/L | 27.2% (摩尔转化率) | — | [124] |
| P. putida KT- PDC2 | 对香豆酸 | 引入PDC合成途径,增强前体PCA的供应 | 控制溶氧 | 补料分批发酵 | 22.7 g/L | 1.0 mol/mol | 0.21 g/(L·h) | [125] |
| P. putida PpY1100-pDVZ21X | 葡萄糖和香草酸 | 引入利用香草酸合成PDC的途径 | 优化培养基成分,控制pH | 补料分批发酵 | 99.9 g/L | 99%(摩尔转化率) | 1.69 g/(L·h) | [126] |
), ArticleFig(id=1164877077611291142, tenantId=1146029695717560320, journalId=1146031712061968385, articleId=1148993957645836657, language=CN, label=表6, caption=
微生物合成2-吡喃酮-4,6-二羧酸(PDC)的研究进展
, figureFileSmall=null, figureFileBig=null, tableContent=
| 生产菌株 | 底物 | 改造策略 | 发酵条件优化 | 生产方式 | 产量 | 得率 | 生产强度 | 参考文献 |
| E.coli GYT7 | 葡萄糖 | 过表达抗反馈抑制的3-脱氧-D-阿拉伯庚酮糖-7-磷酸合成酶,提高前体和优化辅因子的供应水平,并结合计算机模拟分析代谢流 | 偶联pH进行补料 | 补料分批发酵 | 16.7 g/L | 0.20 g/g | 0.17 g/(L·h) | [123] |
| E. coli WJ060、E. coli BL21(DE3)-pET30a-AbquiC和E. coli BL21(DE3)-pRSF-2ABC | 葡萄糖 | 模块化工程,利用葡萄糖合成DHS,接着合成为PCA,最后被催化为PDC | 优化全细胞催化的pH以及负载量等条件 | 补料分批发酵 | 49.2 g/L | 27.2% (摩尔转化率) | — | [124] |
| P. putida KT- PDC2 | 对香豆酸 | 引入PDC合成途径,增强前体PCA的供应 | 控制溶氧 | 补料分批发酵 | 22.7 g/L | 1.0 mol/mol | 0.21 g/(L·h) | [125] |
| P. putida PpY1100-pDVZ21X | 葡萄糖和香草酸 | 引入利用香草酸合成PDC的途径 | 优化培养基成分,控制pH | 补料分批发酵 | 99.9 g/L | 99%(摩尔转化率) | 1.69 g/(L·h) | [126] |
)], attaches=null, journal=Journal(id=1125365342200512522, delFlag=0, nameCn=合成生物学, nameEn=Synthetic Biology Journal, nameHistory1=null, nameHistory2=null, issn=2096-8280, eissn=2097-6364, cn=10-1687/Q, coden=null, periodic=1, language=CN, oaType=0, ccby=null, superviseOffice=null, ownerOffice=null, pubOffice=null, editorOffice=null, officeType=null, aims=null, clcCode=null, officeProv=null, officeCity=null, officeAddr=null, officeZip=null, officeEmail=null, officePhone=null, editDirector=null, officeDirector=null, officeDirectorPhone=null, officeStaffNum=null, officeEmpNum=null, coverPicUrl=DYzLVLWmksc12pIVWhrf0A==, journalPrice=null, startedYear=null, abbrevIsoEn=Synth Biol J, journalRemark=null, publicationField=null, createdTime=null, updatedTime=1760953921208, createdBy=null, updatedBy=13701087609, firstLetterCn=S, firstLetterEn=S, subjectCode=Life Sciences, subjectName=生命科学, subjectCodeEn=Life Sciences, subjectNameEn=null, picCn=DYzLVLWmksc12pIVWhrf0A==, picEn=kDWgmVQ+b/F72HmoCsY5MQ==, jcr=null, cjcr=null, exts=[JournalExt(id=1187090042657849503, language=CN, name=合成生物学, nameHistory1=null, nameHistory2=null, managedBy=, sponsoredBy=, publishedBy=, editorOffice=, officeProv=null, officeCity=null, officeAddr=, officeZip=, editDirector=null, officeDirector=null, officePhone=null, coverPicUrl=null, journalRemark=, submitArticleUrl=null, websiteUrl=https://synbioj.cip.com.cn/, createdTime=1760953921236, updatedTime=1760953921236, createdBy=13701087609, updatedBy=13701087609, submissionGuidelinesUrl=https://synbioj.cip.com.cn/CN/column/column3.shtml, submissionAuthorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/authorLogOn.action, submissionEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorLogOn.action, submissionReviewUrl=https://synbioj.cip.com.cn/Journalx_hcswx/expertLogOn.action, submissionCeEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorCommitteeLogOn.action, submissionAeEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorCommitteeLogOn.action, option={"copyright":""}), JournalExt(id=1187090042716569760, language=EN, name=Synthetic Biology Journal, nameHistory1=null, nameHistory2=null, managedBy=, sponsoredBy=, publishedBy=, editorOffice=, officeProv=null, officeCity=null, officeAddr=, officeZip=, editDirector=null, officeDirector=null, officePhone=null, coverPicUrl=null, journalRemark=, submitArticleUrl=null, websiteUrl=https://synbioj.cip.com.cn/EN/2096-8280/home.shtml, createdTime=1760953921250, updatedTime=1760953921250, createdBy=13701087609, updatedBy=13701087609, submissionGuidelinesUrl=https://synbioj.cip.com.cn/EN/column/column3.shtml, submissionAuthorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/authorLogOn.action, submissionEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorCommitteeLogOn.action, submissionReviewUrl=https://synbioj.cip.com.cn/Journalx_hcswx/expertLogOn.action, submissionCeEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorCommitteeLogOn.action, submissionAeEditorUrl=https://synbioj.cip.com.cn/Journalx_hcswx/editorCommitteeLogOn.action, option={"copyright":""})], databaseList=null, tenantJournalId=1146031712061968385, websiteList=[Website(id=1148243202290737566, webName=null, webTitle=null, webDomain=null, webCopyrigh=null, webIpcNo=null, seoTitle=null, seoKeywords=null, seoDescription=null, tenantJournalId=null, journalId=1146031712061968385, journalNameCn=null, journalNameEn=null, grayFlag=null, tenantId=1146029695717560320, platformId=null, journalGroupId=null, journalGroupNameCn=null, journalGroupNameEn=null, type=1, domain=https://castjournals.cast.org.cn/joweb/hcsw/CN, language=CN, createTime=1751692112753, createBy=18614031015, updateTime=1753514874044, updateBy=18614031015, name=《合成生物学》中文站点, tplId=1146099689490845704, title=合成生物, delFlag=0, indexPage=/home, props=[WebsiteProps(id=1148618543920345123, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1148243202290737566, code=articleTextType, value=kx, createTime=1751781601171, updateTime=1751781601171, creator=18614031015, updator=18614031015), WebsiteProps(id=1148618543886790688, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1148243202290737566, code=banner, value=null, createTime=1751781601163, updateTime=1751781601163, creator=18614031015, updator=18614031015), WebsiteProps(id=1148618543861624863, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1148243202290737566, code=logo, value=https://castjournals.cast.org.cn/joweb/kjdb/CN/file/pic?fileId=IIK1WsoboRPQeScWOsQYDA==, createTime=1751781601157, updateTime=1751781601157, creator=18614031015, updator=18614031015), WebsiteProps(id=1148618543907762210, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1148243202290737566, code=picServerUrl, value=https://castjournals.cast.org.cn/joweb/kjdb/CN/file/pic, createTime=1751781601168, updateTime=1751781601168, creator=18614031015, updator=18614031015), WebsiteProps(id=1148618543899373601, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1148243202290737566, code=staticResourcePath, value=https://castjournals.cast.org.cn/joweb/cast_kjdb_cn_619/, createTime=1751781601166, updateTime=1751781601166, creator=18614031015, updator=18614031015)]), Website(id=1155888775420067847, webName=null, webTitle=null, webDomain=null, webCopyrigh=null, webIpcNo=null, seoTitle=null, seoKeywords=null, seoDescription=null, tenantJournalId=null, journalId=1146031712061968385, journalNameCn=null, journalNameEn=null, grayFlag=null, tenantId=1146029695717560320, platformId=null, journalGroupId=null, journalGroupNameCn=null, journalGroupNameEn=null, type=1, domain=https://castjournals.cast.org.cn/joweb/hcsw/EN, language=EN, createTime=1753514959438, createBy=18614031015, updateTime=1753514959438, updateBy=18614031015, name=《合成生物学》英文站点, tplId=1146101810881728533, title=Synthetic Biology Journal, delFlag=0, indexPage=/home, props=[WebsiteProps(id=1155890707861725282, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1155888775420067847, code=articleTextType, value=kx, createTime=1753515420165, updateTime=1753515420165, creator=18614031015, updator=18614031015), WebsiteProps(id=1155890707849142367, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1155888775420067847, code=banner, value=null, createTime=1753515420162, updateTime=1753515420162, creator=18614031015, updator=18614031015), WebsiteProps(id=1155890707840753758, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1155888775420067847, code=logo, value=https://castjournals.cast.org.cn/joweb/kjdb/CN/file/pic?fileId=IIK1WsoboRPQeScWOsQYDA==, createTime=1753515420160, updateTime=1753515420160, creator=18614031015, updator=18614031015), WebsiteProps(id=1155890707857530977, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1155888775420067847, code=picServerUrl, value=https://castjournals.cast.org.cn/joweb/kjdb/CN/file/pic, createTime=1753515420164, updateTime=1753515420164, creator=18614031015, updator=18614031015), WebsiteProps(id=1155890707853336672, tenantId=1146029695717560320, journalId=null, journalGroupId=null, siteId=1155888775420067847, code=staticResourcePath, value=https://castjournals.cast.org.cn/joweb/cast_kjdb_cn_619/, createTime=1753515420163, updateTime=1753515420163, creator=18614031015, updator=18614031015)])], journalTitle=合成生物学, weixinUrl=null, journalUrl=null, iacademicId=null, status=0, seqNo=null, journalTitleEn=Synthetic Biology Journal, journalPhotoCn=DYzLVLWmksc12pIVWhrf0A==, journalPhotoEn=kDWgmVQ+b/F72HmoCsY5MQ==, journalFirstLetter=S, journalRecommend=null, journalNew=null, journalCollection=null, jcrJf=null, cjcrJf=null, jcrJfStr=null, cjcrJfStr=null, submissionFirstDecision=null, sciSubjectClassification=null, casSubjectClassification=null, citeScore=null, totalCitationFrequency=null, icpCode=null, psCode=null, advertisingLicenseCode=null, copyrightInformation=null, country=null, option=, provinceCode=null, provinceName=null, collectFlag=false), detailUrlCn=https://castjournals.cast.org.cn/joweb/hcsw/CN/10.12211/2096-8280.2024-011, detailUrlEn=https://castjournals.cast.org.cn/joweb/hcsw/EN/10.12211/2096-8280.2024-011, pdfUrlCn=https://castjournals.cast.org.cn/joweb/hcsw/CN/PDF/10.12211/2096-8280.2024-011, pdfUrlEn=https://castjournals.cast.org.cn/joweb/hcsw/EN/PDF/10.12211/2096-8280.2024-011, aliStartDate=null, aliEndDate=null, collectionFlag=false, citedCount=null, citedUrl=null, reference=null)
全屏
文章导航
PDF下载
383
184
关闭全屏
北京市海淀区学院南路86号
010-62199257
qkjq@cast.org.cn
