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化学进展 2014

微生物电化学系统电子中介体

DOI: 10.7536/PC140740, PP. 1859-1866

刘利丹,肖勇,吴义诚,陈必链,赵峰

Keywords: 微生物电化学系统,胞外电子传递,间接电子传递,电子中介体,吩嗪,核黄素

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Abstract:

电化学活性微生物与电极之间的胞外电子传递在微生物电化学系统(microbialelectrochemicalsystems,MESs)产能、生物修复等功能的实现中起着关键作用.目前,研究者对微生物胞外电子传递机理了解有限,限制了MESs的应用.相比于需要微生物功能蛋白与电极接触才能发生的直接电子传递,间接电子传递可通过具有可逆氧化还原活性的电子中介体(electrontransfermediators,ETMs)实现电子的传递,从而有效提高微生物胞外电子传递效率.在间接电子转移过程中,ETMs起着中间电子受体和中间电子供体的作用,即被还原后可将电子传递给最终电子受体并被重新还原;理论上每个ETMs分子可以循环数千次,因此ETMs对特定环境下终端氧化物(如铁离子)的循环有着极其显著的作用.本文系统总结了MESs中ETMs及间接电子传递机制近年来的研究进展,并且在此基础上探讨了ETMs在MESs中的研究趋势,以期推动MESs在生物修复、能源生产方面的实际应用.

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