将马铃薯皮的厌氧消化与固定在香蕉叶上的甲烷营养菌的甲醇生产相结合。

Integrating anaerobic digestion of potato peels to methanol production by methanotrophs immobilized on banana leaves.

机构信息

Department of Chemical Engineering, Konkuk University, Seoul 05029, Republic of Korea.

出版信息

Bioresour Technol. 2021 Mar;323:124550. doi: 10.1016/j.biortech.2020.124550. Epub 2020 Dec 16.

DOI:10.1016/j.biortech.2020.124550

Abstract

In the present study, potato peels were subjected to anaerobic digestion (AD) to produce biogas (methane [CH] and carbon dioxide), which was subsequently used as a substrate for methanol production by methanotrophs. AD resulted in high yields of up to 170 L CH/kg total solids (TS) from 250 mL substrate (2% TS, w/v). Under optimized conditions, maximum methanol production of 4.97 and 3.36 mmol/L from raw biogas was observed in Methylocella tundrae and Methyloferula stellata, respectively. Immobilization of methanotrophs on banana leaves showed loading of up to 156 mg dry cell mass/g support. M. tundrae immobilized on banana leaves retained 31.6-fold higher methanol production stability, compared to non-immobilized cells. To the best of our knowledge, this is the first study on immobilization of methanotrophs on banana leaves for producing methanol from potato peels AD-derived biogas. Such integrative approaches may be improved through process up-scaling to achieve sustainable development.

摘要

在本研究中，马铃薯皮经过厌氧消化（AD）以产生沼气（甲烷[CH]和二氧化碳），随后沼气被甲烷营养菌用作生产甲醇的底物。AD 可从 250 毫升底物（2% TS，w/v）中获得高达 170 L CH/kg 总固体（TS）的高产量。在优化条件下，从原始沼气中观察到嗜甲基菌（Methylocella tundrae）和甲基螺旋菌（Methyloferula stellata）的甲醇最大产量分别为 4.97 和 3.36 mmol/L。将甲烷营养菌固定在香蕉叶上，载体的最大干细胞质量负载量可达 156 mg/g。与非固定细胞相比，固定在香蕉叶上的嗜甲基菌（Methylocella tundrae）保留了 31.6 倍更高的甲醇生产稳定性。据我们所知，这是首次研究将甲烷营养菌固定在香蕉叶上，以从马铃薯皮 AD 产生的沼气中生产甲醇。通过工艺放大实现可持续发展，可以改进这种综合方法。

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将马铃薯皮的厌氧消化与固定在香蕉叶上的甲烷营养菌的甲醇生产相结合。

Integrating anaerobic digestion of potato peels to methanol production by methanotrophs immobilized on banana leaves.

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