微生物碳酸酐酶(CA)活性的碳捕获与生物胶结研究综述与展望

Wilson Mwandira, Maria Mavroulidou, Michael J. Gunn, Diane Purchase, Hemda Garelick, Jonathan Garelick
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引用次数: 1

摘要

生物胶结,即通过微生物的代谢活动生产仿生水泥,为各种土木和环境工程应用提供了令人兴奋的新前景。本文对生物胶结途径进行了系统的文献综述,该途径利用微生物吸收二氧化碳的碳酸酐酶(CA)活性来产生生物胶结。其目的是将该技术在土木和(地质)环境工程中应用于二氧化碳中性或负过程的未来发展。在筛选了2002年至2023年间发表的248篇可能相关的同行评议期刊论文后,38篇研究ca -生物胶结的论文被纳入综述。其中一些研究使用纯CA酶,而不是细菌产生的CA。在这些研究中,7项研究使用生物胶结剂用于自修复混凝土,6项用于二氧化碳封存,10项用于岩土工程应用,15项用于(地质)环境应用。共对34株细菌进行了研究,并确定了其生长和酶活性的最佳条件。这篇综述的结论是,这个话题很少被研究;需要在实验室和实地进行更多的研究(特别是长期的实地实验,这是完全缺乏的)。ca -生物胶结的数值模拟和动力学参数的研究尚未发现。因此,本文参考了更广泛研究的ca途径co2封存领域,以确定其他值得进一步研究的微生物和用于数值模拟的反应动力学参数。最后,讨论了需要解决的挑战和未来的研究需求。
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Concurrent Carbon Capture and Biocementation through the Carbonic Anhydrase (CA) Activity of Microorganisms -a Review and Outlook
Abstract Biocementation, i.e., the production of biomimetic cement through the metabolic activity of microorganisms, offers exciting new prospects for various civil and environmental engineering applications. This paper presents a systematic literature review on a biocementation pathway, which uses the carbonic anhydrase (CA) activity of microorganisms that sequester CO 2 to produce biocement. The aim is the future development of this technique for civil and (geo-)environmental engineering applications towards CO 2 -neutral or negative processes. After screening 248 potentially relevant peer-reviewed journal papers published between 2002 and 2023, 38 publications studying CA-biocementation were considered in the review. Some of these studies used pure CA enzyme rather than bacteria-produced CA. Of these studies, 7 used biocementation for self-healing concrete, 6 for CO 2 sequestration, 10 for geotechnical applications, and 15 for (geo-)environmental applications. A total of 34 bacterial strains were studied, and optimal conditions for their growth and enzymatic activity were identified. The review concluded that the topic is little researched; more studies are required both in the laboratory and field (particularly long-term field experiments, which are totally lacking). No studies on the numerical modelling of CA-biocementation and the required kinetic parameters were found. The paper thus consulted the more widely researched field of CO 2 sequestration using the CA-pathway, to identify other microorganisms recommended for further research and reaction kinetic parameters for numerical modelling. Finally, challenges to be addressed and future research needs were discussed.
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