Bioengineering and Environmental Centre (BEEC), CSIR-Indian Institute of Chemical Technology (CSIR-IICT), Hyderabad 500 607, India.
Bioresour Technol. 2012 Dec;125:291-9. doi: 10.1016/j.biortech.2012.08.060. Epub 2012 Sep 3.
Microaerophilic microenvironment at biocathode was evaluated for electrogenesis along with the polyhydroxyalkanoates (PHA) accumulation in bio-electrochemical system (BES). The electrogenic activity (512 mV; 15.2 mW/m(2)) was extended for longer periods (144 h) which might be attributed to the lowering of losses due to the controlled microbial metabolism. Growth limiting stress at cathode due to lower oxygen levels and its effective utilization by the protons and electrons coming from anode, might have diverted the microbial metabolism towards PHA synthesis instead of oxidation. PHA accumulation (19% of dry cell weight (DCW)) was observed with higher hydroxy butyrate (HB) (89%) concentration at 48 th h in the cathodic biocatalyst and was re-utilized by the end of experiment. Bio-electro kinetics studied through voltammetry and Tafel analysis further supported the observed electrogenesis in microaerophilic reduction microenvironment, in terms of redox catalytic currents, Tafel slopes, exchange current densities and polarization resistance.
在生物电化学系统 (BES) 中,评估了生物阴极的微需氧微环境对电生成和聚羟基烷酸酯 (PHA) 积累的影响。电生成活性(512 mV;15.2 mW/m(2))延长了更长的时间(144 h),这可能归因于由于控制微生物代谢而降低的损失。由于较低的氧气水平以及来自阳极的质子和电子的有效利用,在阴极造成的生长限制压力可能导致微生物代谢转向 PHA 合成而不是氧化。在阴极生物催化剂中,在第 48 小时观察到 PHA 积累(占干细胞重量 (DCW) 的 19%),并且在实验结束时被重新利用,同时观察到 HB(89%)浓度更高。通过伏安法和塔菲尔分析研究生物电化学动力学,进一步支持了在微需氧还原微环境中观察到的电生成,就氧化还原催化电流、塔菲尔斜率、交换电流密度和极化电阻而言。
